Annual report of the Australian Meningococcal Surveillance Programme, 1998

This article published in Communicable Diseases Intelligence Volume 23, No 12, 25 November 1999 contains the annual report of the the National Neisseria Network, which has undertaken meningococcal isolate surveillance by means of a collaborative laboratory-based initiative since 1994.

Page last updated: 02 December 1999

A print friendly PDF version is available from this Communicable Diseases Intelligence issue's table of contents.


The Australian Meningococcal Surveillance Programme1

Introduction | Methods | Results | Discussion | Acknowledgement | References

Abstract

The National Neisseria Network has undertaken meningococcal isolate surveillance by means of a collaborative laboratory-based initiative since 1994. The phenotype (serogroup, serotype and serosubtype) and antibiotic susceptibility of 323 isolates of Neisseria meningitidis from invasive cases of meningococcal disease were determined in 1998. Ninety per cent of the invasive isolates were either serogroup B or C. Serogroup B strains predominated in all States and Territories and were isolated from sporadic cases of invasive disease. Serogroup B phenotypes were diverse. Serogroup C isolates were most prominent in New South Wales, especially in adolescents and young adults. C:2a:P1.5 was the most frequently encountered phenotype and C:2b:P1.5,2 strains were also distributed widely. About three-quarters of all isolates showed decreased susceptibility to the penicillin group of antibiotics (MIC 0.06 to 0.5 mg/L). Four isolates showed reduced susceptibility to rifampicin, one to ciprofloxacin and one to chloramphenicol. Commun Dis Intell 1999;23:317-323.

Introduction

Invasive meningococcal diseases continued to attract considerable public attention in 1998. The manifestations of meningococcal disease may range from the mild and even subclinical to the rapidly progressive and fatal. Many of the reasons for these different responses remain unknown. However, the host response and outcome of disease in an individual patient and the patterns of the infection within a community may be materially altered by the characteristics of the infecting organism.1,2 The public health response to a suspected outbreak or cluster of cases is also influenced by certain features of the meningococci concerned, for example vaccines are available for some serogroups of meningococci but not for others, and certain phenotypes have been linked to disease outbreaks.

A national programme for the examination of strains of Neisseria meningitidis (N. meningitidis) from cases of invasive meningococcal disease was commenced in 1994 with the co-operation and participation of reference laboratories in each State and Territory. This laboratory-based activity is designed to supplement data from existing clinical notification schemes by adding information on the phenotype (the serogroup, the serotype and subserotype) and antibiotic susceptibility of invasive isolates to clinical data. In certain instances other laboratory investigations, mainly molecular studies, are undertaken to provide further epidemiological information.

Reports summarising data gathered since the inception of the programme were published in CDI.3-7 The following report deals with the calendar year 1998.

Top of page

Methods

The National Neisseria Network (NNN) is a collaborative programme for the laboratory surveillance of the pathogenic Neisseria, N. meningitidis and N. gonorrhoeae.3-7 A network of reference laboratories in each State and Territory (see Acknowledgements) performs meningococcal isolate surveillance. Each case was based upon isolation of a meningococcus from a normally sterile site. Information on the site of infection, the age and sex of the patient and the outcome (survived/died) of the infection was sought. The isolate surveillance programme categorises cases on the basis of site of isolation of the organism. Where an isolate is grown from both blood and CSF cultures in the same patient, the case is classified as one of meningitis. It is recognised that the total number of cases and particularly the number of cases of meningitis, for example, where there was no lumbar puncture or else where lumbar puncture was delayed and culture was sterile, was underestimated. However, the above approach has been used since the beginning of this programme and is continued for comparative purposes.

Phenotyping of invasive isolates of meningococci by serotyping and serosubtyping was based on the detection of outer membrane protein antigens using a standard set of monoclonal antibodies obtained from Dr. J. Poolman, National Institute for Public Health (RIVM), The Netherlands.

Antibiotic susceptibility was assessed by determining the minimal inhibitory concentration (MIC) to antibiotics used for therapeutic and prophylactic purposes. This programme uses the following parameters to define the various levels of penicillin susceptibility/resistance when determined by a standardised agar plate dilution technique:
Sensitive: MIC ≤ 0.03 mg/L
Less sensitive: MIC 0.06 - 0.5 mg/L
Relatively resistant: MIC ≥ 1 mg/L

Strains with MICs which place them in the category of 'sensitive' or 'less sensitive' would be considered to be amenable to penicillin therapy when used in currently recommended doses.

Top of page

Results

Number of isolates

A total of 323 invasive isolates of meningococci was examined in 1998. There were 113 isolates from patients whose infections were acquired in New South Wales (35% of all isolates), 81 (25%) from Queensland, 42 (13%) from Western Australia, 40 (12.5%) from Victoria, 24 (7.5%) from South Australia, 13 (4%) from Tasmania, 9 (3%) from the Northern Territory and 1 (0.3%) from the Australian Capital Territory (Table 1).

Table 1. Neisseria meningitidis isolates, 1998, by State or Territory and age group

  Age group (years)
<1 1-4 5-9 10-14 15-19 20-24 25-44 45-64 65+ NS All
Qld
5
26
7
4
9
6
17
7
6
0
81
NSW
15
32
6
5
25
10
9
6
4
1
113
ACT
0
1
0
0
0
0
0
0
0
0
1
Vic
6
12
3
2
5
4
5
3
1
0
41
Tas
4
5
0
1
1
0
1
0
1
0
13
SA
5
4
1
2
1
2
1
1
2
2
24
WA
1
14
2
0
10
7
4
2
2
0
42
NT
2
3
1
1
0
0
0
1
1
0
9
Total n
38
97
20
15
51
29
30
20
20
3
323
%
11.8
30
6.2
4.6
15.7
9
9.3
6.2
6.2
1
100

NS Not stated


Seasonality

Thirty-eight (11.7%) of cases occurred between 1 January and 31 March, 79 (24.5%) between 1 April and 30 June, 132 (40.9%) between 1 July and 30 September and 74 (22.9%) between 1 October and 31 December. A winter peak of meningococcal disease is usual.

Age group

The age distribution of patients infected with invasive isolates in each State and Territory is shown in Table 1. Nationally, the peak incidence of meningococcal disease occurred in those 4 years and under. Those aged less than 1 year or in the 1-4 year age group accounted for 11.8% and 30% of cases respectively. A secondary peak was noted in the 15-19 year age group when 51 cases accounting for 15.7% of the total were recorded. A further 29 cases (9%) occurred in those aged 20-24 years. Western Australia differed from the national pattern in that the number of cases of invasive disease in those aged 15-24 years was higher than for those aged 4 years or less. In Queensland, South Australia and Victoria, the secondary peak in the young adult group was half or less than in the infant group. New South Wales approximated the national average age distribution of disease.

Serogroup, serotype and serosubtype (phenotype) distribution

The distribution of the isolates by serogroup is shown in Table 2. Nationally, 204 serogroup B isolates represented 64% of all strains, the same proportion as in 1997. The 81 serogroup C strains (25%) were less than the number and proportion detected in 1997. There was an increase in the number (18) and proportion (6%) of serogroup Y strains in 1998. Nine serogroup W135 meningococci were also identified. Seven isolates were not serogroupable. No serogroup A isolates were encountered in 1998.

Table 2. Neisseria meningitidis isolates, 1998, by State or Territory and serogroup

State/Territory
Serogroup Total
B C A Y W135 NG*   n %
n % n %   n % n % n   %  
Qld
56
70.4
12
13.6
0
6
7.5
2
2.5
5
 
6
81
25
NSW
53
47
50
44
0
6
5.5
4
3.5
0
 
113
35
ACT
1
100
0
 
0
0
 
0
 
0
 
1
0.3
Vic
29
72.5
7
17.5
0
4
10
0
 
0
 
40
12.5
Tas
9
69
2
15.5
0
0
 
0
 
2
15.5
13
4
SA
14
58.3
7
29.1
0
11
4.2
2
8.4
0
 
24
7.5
WA
36
87
4
8
0
1
2.5
1
2.5
0
 
42
13
NT
8
89
1
11
0
0
 
0
 
0
 
9
2.5
Total
204
64
81
25
0
18
6
99
3
7
2
323
100

*NG = non-groupable

Top of page
The regional data show some important differences in the distribution of serogroups.

Serogroup B predominated in aggregated national data and especially in Western Australia (87% of isolates), Victoria (72%), the Northern Territory (89%) and Queensland (70%). In contrast, in New South Wales the 53 group B strains accounted for 47% of isolates and in South Australia group B isolates were nearly 60% of the total. Group B disease comprised unlinked and apparently sporadic cases. Serogroup C isolates were again concentrated in New South Wales. Fifty group C meningococci or 62% of all serogroup C strains isolated in Australia were from infections there. Group C meningococci represented 44% of the New South Wales isolates and about 30% of South Australian meningococci. Numbers and proportions of group C strains were much lower in other States and Territories. There was a single group C isolate in the Northern Territory, 2 in Tasmania,   11 (14%) in Queensland, 7 (17%) in Victoria and 4 (8%) in Western Australia. No clusters of serogroup   C infection were identified.

The distinct serogroup distribution in New South Wales had an age specific pattern. Serogroup B isolates predominated in the 0-4 year age group (29 of 47) isolates whereas serogroup C strains were most prominent (20 of 35) in the adolescent and young adult age group (15-24 years).

There was considerable phenotypic heterogeneity amongst invasive isolates as determined by serotyping and serosubtyping. The predominant serotypes / serosubtypes in each State and Territory are shown in Table 3, Western Australia excepted. Serogroup B meningococci are more difficult to characterise by serological methods and a number could not be phenotyped. B:4:P1.4 strains were present in New South Wales, Queensland, Victoria and South Australia, and B:15:P1.7 strains in New South Wales, Queensland, Victoria, and South Australia.

Table 3. Most frequently isolated serotypes and serosubtypes and phenotypes of N. meningitidis of interest, by State and Territory in 1998

State/Territory
Serogroup
B C
Serotype:serosubtype Serotype:serosubtype
Qld
4:P1.4
4 (3, 6)*
2b:P1.5,2
3 (0, 10)*
 
NT:P1.4
3 (9, 4)
2a:P1.5
4 (1, 4)
 
15:P1.7
1 (3)
2a:P1.5,2
0 (3, 4)
 
2b:P1.10
1 (2)
2b:P1.2
0 (3)
NSW
4:P1.4
5 (17, 11)
2a:P1.5
23 (39, 15)
 
NT:NST
8 (13, 9)
2b:P1.5,2
6 (8, 10)
 
2b:P1.10
4 (11, 8)
2a:P1.5,2
8 (3, 2)
 
15:P1.7
1 (7)
2b:P1.2
0 (2, 0)
Vic
NT:P1.4
11 (8, 13)
2a:P1.5
1 (1)
 
15:P1.7
1 (3)
2b:P1.10
2 (1)
 
4:P1.4
2 (3, 2)
2b:P1.2
2 (1)
 
2b:P1.10
1 (2)
SA
15:P1.7
3
2b:P1.5,2
2
 
4:NST
3
 
4:P1.4
1
Tas
2b:nst
2
2b:P1.2
1 (2)
ACT
Single isolate only
NT
2b:nst
5
2a:nst
1

* The numbers of isolates of each phenotype in 1997 and 1996 are shown in parenthesis

Top of page
There was less heterogeneity amongst serogroup C meningococci. All isolates were either serotype 2a or 2b and the serosubtypes present were either P1.5 or P1.2 or else a combination of both. There were 28 serogroup C strains of phenotype 2a:P1.5 (54% of all group C strains phenotyped). Twenty-three of these were found in New South Wales. Strains of this phenotype were also isolated in Queensland and Victoria. The phenotype 2b:P1.5,2 was also prominent.

Serogroup Y strains were either serotype 14 or else not serotypeable.

Site of isolation

There were 84 isolates from CSF either alone or with a blood culture isolate and 235 from blood cultures alone. There were four isolates from other sterile sites including synovial fluid and skin lesions.

Outcome data for 1998

Outcome data (survived or died) were available for 202 patients (62.5%). Eighteen deaths were recorded (9%) (Table 4). Outcomes were available in 122 serogroup B infections (59%) and 61 serogroup C infections (74%). There were four deaths in serogroup B infections and 10 in serogroup C infections (p<0.002 ). Where outcomes were known, there were four deaths in 44 patients (9%) with meningitis. Two patients were infected with serogroup B and two with serogroup C strains. Fourteen deaths were recorded in 157 bacteraemic patients (9 %). There were 86 cases of serogroup B meningococcal bacteraemia with 2 deaths and another 47 cases were caused by serogroup C strains among whom 8 fatalities were recorded. Three of 8 patients with serogroup Y septicaemia died. There was one fatal case of septicaemia with serogroup W135.

Table 4. Outcome of meningitic and septicaemic cases of meningococcal infection by serogroup, 1998

Disease type
Outcome Serogroup  
B C Y W135 NG* Total
Meningitis
Survived
34
4
1
1
0
40
Died
2
2
0
0
0
4
Total
36
6
1
1
0
44
Septicaemia
Survived
84
47
5
5
2
143
Died
2
8
3
1
0
14
Total
86
55
8
6
2
157
All cases**
Total
122
61
10
7
2
202
Died
4
10
3
1
0
18 (9%)

* Non groupable
** Includes one serogroup Y strain from a joint aspirate from a patient who survived.


Antibiotic susceptibility surveillance of invasive meningococcal isolates

Penicillin

Three-hundred and two isolates of the 323 strains were tested for their susceptibility to penicillin. Using defined criteria, 75 strains (25%) were fully sensitive to penicillin and 227 (75%) less sensitive (MIC 0.06 - 0.5 mg/L). These proportions differ little from 1997 data. The penicillin MICs recorded ranged between 0.015 and 0.5 mg/L. Only four isolates had MICs of 0.5 mg/L.

Other antibiotics

All 302 isolates which were tested for susceptibility to ceftriaxone (and by extrapolation to other third generation cephalosporins), were susceptible to these therapeutic agents. A single isolate had decreased susceptibility to chloramphenicol. Four meningococci had raised MICs to rifampicin (MICs of 1 mg/L) and one to ciprofloxacin (MIC   0.25 mg/L) (sulphonamide testing was not performed).

Top of page

Discussion

The total of 323 isolates examined by NNN laboratories in the Australian Meningococcal Surveillance Programme in 1998 was less than the 343 available in 1997. From 1994 onwards, the number of isolates examined each year by the NNN has increased. This has been in part at least the result of improved surveillance, although increases in disease incidence have also occurred. The decrease in overall numbers in 1998 reverses this trend, but this did not occur in all jurisdictions. The numbers of isolates available in New South Wales and Victoria were between 70% and 75% of the total examined in 1997. In Western Australia and Queensland the numbers of isolates increased, from 23 to 42 and 62 to 81 respectively. Although considerable public attention was focussed on meningococcal disease in South Australia in 1998, the number of cases was essentially unchanged from 1997. The number of isolates available for examination will always be less than the number of clinically notified cases because clinical surveillance case definitions include culture negative cases. A number of clinical cases were confirmed only by non-culture based laboratory examinations. These procedures include nucleic-acid-based amplification assays (NAA) and serological examination. These cases were not included in this year's analysis of isolate-based surveillance. Some of the techniques in use can provide additional data on the serogroup of the isolate. It is anticipated that laboratory confirmation of invasive meningococcal disease by non-culture based methods will continue to increase. NNN laboratories may be contacted for advice regarding these tests.

The ratio of cases of meningitis to bacteraemia was significantly lower in 1998, accentuating a trend noted in 1997 (Figure 1). From 1994 to 1996, the ratio of cases of meningitis to bacteraemia was close to 1.0:1 in NNN data. In 1997 this ratio decreased to 0.6:1 and in 1998 further declined to 0.3:1. NNN case definitions, which are based on site of isolation, tend to overestimate the number of bacteraemic cases. This is because those cases of clinical meningitis where only a blood culture was positive were regarded as bacteraemias in NNN data. It has been recognised anecdotally that there is an increasing reluctance on the part of clinicians to perform lumbar puncture early in cases of suspected meningitis or to omit the investigation altogether. However, NNN case definitions have been constant over the past 5 years. Another factor which may impact on this changing picture, is the continuing emphasis on early antibiotic treatment for meningococcal disease. It is more feasible to obtain a blood culture when intravenous antibiotics are administered than to perform a lumbar puncture, so this may also influence data on categorisation. However, it would appear that the reluctance or inability to obtain CSF early in the disease, rather than a shift in disease manifestations, is the principal reason for the change in isolation pattern observed. Again, non-culture based diagnosis may assist in the clarification of disease manifestations.

The predominant disease pattern observed was one of sporadic infection with serogroup B meningococci. The proportion of serogroup C cases was less in 1998 than in 1997, which has relevance to decisions regarding the use of conjugate group C vaccines.9 Serogroup C cases were also sporadic in nature in 1998. Serogroup C disease was most often encountered in New South Wales, but infrequently in other States and Territories. No serogroup A meningococci were isolated in 1998. Also of interest was the increased number and proportion of cases of serogroup Y infection. Although distributed in low numbers in a number of States, they represented about 5% of all infections. Serogroup Y infections have increased in some parts of the United States of America in recent years.10

Children aged 4 years or less were the group most frequently infected. A secondary incidence peak was noted in young adults and adolescents, especially in Western Australia and New South Wales. Serogroup C disease occurred more often in the young adult age group. This picture of serogroup B and C disease occurring as sporadic cases is typical of the pattern of meningococcal disease in developed countries. Clusters of cases of serogroup C infection have been present in recent years but were not seen in 1998.5,6
Top of page

Phenotyping data obtained on the basis of serotyping and serosubtyping was again available from all but one centre in 1998. The heterogeneity of serogroup B isolates present in Australia was confirmed. Of interest amongst the group B strains were phenotypes B:4:P1.4 and B:15:P1.7 associated with hyperendemic disease in New Zealand and Europe respectively. B:4:P1.4 strains were encountered in low numbers in a number of States.

Of some interest in the reports from 1996 and 19975,6 was the appearance and spread of the phenotypes C:2a:P1.5 and C:2a:P1.5,2. These phenotypes have been implicated in hyperendemic meningococcal disease in Canada for a number of years8 and have also been reported in Europe. They were responsible for clusters of cases in Western Sydney in 1996 and 1997. The C:2a:P1.5 phenotype was responsible for 23 cases of invasive disease in New South Wales in 1998, but no case clusters were recognised. This phenotype was also present in Queensland and Victoria in 1998.

Figure 1. Numbers of meningococcal isolates from CSF and blood culture, 1994 to 1998

Figure 1. Numbers of meningococcal isolates from CSF

Overall, the mortality recorded in assessable cases was   9%, higher than the 6% observed in previous years. A higher mortality rate was observed with serogroup C and serogroup Y infections than with serogroup B cases, but outcome data was incomplete. Although serogroup C strains have been associated with increased mortality overseas, other factors for which data were not available may explain this difference, such as age and time from onset to presentation and treatment. The increase in mortality was observed in a number of States.

Continuing interest has been shown in the decrease in susceptibility of meningococci to penicillin in many parts of the world. Further, other isolates have occasionally been shown to be resistant to other antibiotics which are used currently for either therapeutic or prophylactic purposes in meningococcal disease. This programme therefore includes routine examination of the antibiotic susceptibility of invasive isolates as part of its surveillance. Trend data indicates that since 1994 there has been an increase in the proportion of invasive meningococci showing some decrease in penicillin susceptibility. In 1994, 52% of strains were in the 'less sensitive' range (MIC 0.06 - 0.5   mg/L). In 1995, 155 (63%) of 247 strains tested were 'less sensitive'. The proportion of less sensitive isolates increased further to 74% of 297 isolates in 1996. This proportion remained unchanged in 1997 (73%) and no further change was recorded in 1998. The isolation of a meningococcus with an MIC in the less sensitive range does not mean that therapeutic failure will occur, but the increase in the number and proportion of strains in this category is rather an epidemiological marker of the slow progression to resistance.

The definition of what constitutes 'resistance' to the prophylactic agent rifampicin varies. This programme has chosen to monitor the number of isolates with MICs of 1 mg/L or more. There were four isolates with rifampicin MICs of 1 mg/L or more in 1998. One isolate was chloramphenicol resistant and another had decreased susceptibility to ciprofloxacin.

The programme has examined a total of more than 1,400 strains from all States and Territories since 1994 and has assisted in clarifying and expanding information on invasive meningococcal isolates in Australia. The nature and high public recognition of meningococcal disease suggests that these efforts should continue. For further details the relevant NNN member should be contacted (see Acknowledgements for contact numbers).

Top of page

Acknowledgements

Isolates were received in the reference centres from many laboratories throughout Australia. The considerable time and effort involved in forwarding these strains is recognised and these efforts are greatly appreciated. These data could not have been provided without this assistance and the help of clinical colleagues and Public Health personnel.

The Commonwealth Department of Human Services and Health provided a grant for the National Neisseria Network.

Participants in the Australian Meningococcal Surveillance Programme: (to whom strains should be referred and enquires directed)

QUEENSLAND
John Bates, Denise Murphy, Helen Smith,
Public Health Microbiology
Queensland Health Scientific Services
39 Kessels Road
COOPERS PLAINS, QLD 4108
Phone: (07) 3274 9101, Fax: (07) 3274 9008,
E-mail: batesj@health.qld.gov.au

WESTERN AUSTRALIA
Mr. C. Richardson, Mr. P. Campbell, Ms K. Stowe
Department of Microbiology
Princess Margaret Hospital for Children
1 Thomas Street
SUBIACO WA 6008
Phone: (08) 9340 8273, Fax: (08) 9380 4474
E-mail: chris.richardson@health.wa.gov.au

TASMANIA
Dr. K. Ott, Mr Mark Gardam
Department of Microbiology and Infectious Diseases
Royal Hobart Hospital
GPO Box 1061L
HOBART, TAS 7001
Phone: (03) 6238 8410

SOUTH AUSTRALIA
Mr A. Lawrence
Microbiology Department
Women's and Children's Hospital
72 King William Road
NORTH ADELAIDE, SA 5006
Phone: (08) 8204 7326; Fax: (08) 8204 6376
E-mail: lawrencea@wch.sa.gov.au

VICTORIA
Dr. J. Griffith, Dr. G. Hogg
Microbiological Diagnostic Unit
University of Melbourne
PARKVILLE, VIC 3052
Phone: (03) 9344 5701, Fax: (03) 9344 7833
E-mail j.griffith@microbiology.unimelb.edu.au
Top of page

NEW SOUTH WALES
A/Prof. J. Tapsall
Microbiology Department
The Prince of Wales
RANDWICK, NSW 2031
Phone: (02) 9382 9079; Fax: (02) 9398 4275
E-mail: j.tapsall@unsw.edu.au

OR

A/Prof. Rosemary Munro
Department of Microbiology and Infectious Diseases
SWAPS
Locked Mail Bag 90
LIVERPOOL, NSW 2179
Phone: (02) 9828 5128, Fax: (02) 9828 5129
E-mail: r.munro@unsw.edu.au

ACT
Dr. P. Collignon, Mr P. Southwell
Department of Microbiology
Royal Canberra Hospital
PO Box 11
WODEN, ACT 2606
Phone: (02) 6244 2425
E-mail: peter.collignon@dpa.act.gov.au

NORTHERN TERRITORY
Dr G. Lum
Microbiology Department
Royal Darwin Hospital
CASUARINA, NT
Phone: (08) 8922 8834, Fax (08) 8922 8843
E-mail: glum@ozE-mail.com.au

Author affiliations

1. Corresponding author: Assoc. Prof. John Tapsall, Department of Microbiology, The Prince of Wales Hospital, High Street, Randwick, NSW 2031

Top of page

References

1. Maiden MCJ, Bygraves JA, Feil E, et al. Multilocus sequence typing: a portable approach to the identification of clones within populations of pathogenic microorganisms. Proc Natl Acad Sci USA 1998;95:3140-3145.

2. Munro R, Tapsall J. Meningococcal disease in Australia. Commun Dis Intell 1996;20:368-371.

3. National Neisseria Network. Meningococcal Isolate Surveillance Australia 1994. Commun Dis Intell 1995:19:286-289.

4. National Neisseria Network. Meningococcal Isolate Surveillance Australia 1995. Commun Dis Intell 1996;20:422-424.

5. The Australian Meningococcal Surveillance Programme. Annual report of the Australian Meningococcal Surveillance Programme 1996. Commun Dis Intell 1997;21:217-221.

6. Australian Meningococcal Surveillance Programme. Annual report of the Australian Meningococcal Surveillance Programme. Commun Dis Intell 1998;22:205-211.

7. Australian Gonococcal Surveillance Programme. Penicillin sensitivity of gonococci in Australia: development of an Australian gonococcal surveillance programme. Br J Vener Dis 1984;60:226-230.

8. Ashton FE, Ryan JA, Borcyzk DA, Caugant DA, Mancino L, Huang D. Emergence of a virulent clone of Neisseria meningitidis serotype 2a that is associated with meningococcal group C disease. Canada J Clin Microbiol 1991;29:2489-2943.

9. Maiden MCJ, Spratt BG. Meningococcal conjugate vaccines: new opportunities and new challenges. Lancet 1999:354:615-616.

10. CDC. Serogroup Y meningococcal disease - Illinois, Connecticut, and selected areas, United States, 1989-1996. MMWR 1996;45:1010-1013.


This article was published in Communicable Diseases Intelligence Volume 23, No 12, 25 November 1999.

Communicable Diseases Intelligence subscriptions

Sign-up to email updates: Subscribe Now

This issue - Vol 23, No 12, 25 November 1999