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The contribution of PCR testing to influenza and pertussis notifications in Australia

Published online by Cambridge University Press:  26 June 2015

M. C. KACZMAREK*
Affiliation:
Queensland Children's Medical Research Institute, Brisbane, QLD, Australia School of Public Health, The University of Queensland, Herston, QLD, Australia
R. S. WARE
Affiliation:
School of Public Health, The University of Queensland, Herston, QLD, Australia Child Health Research Centre, The University of Queensland, Herston, QLD, Australia
S. B. LAMBERT
Affiliation:
Queensland Children's Medical Research Institute, Brisbane, QLD, Australia Child Health Research Centre, The University of Queensland, Herston, QLD, Australia Communicable Diseases Unit, Queensland Health, Brisbane, QLD, Australia
*
*Author for correspondence: Ms. M. C. Kaczmarek, Queensland Children's Medical Research Institute, Level 4, Foundation Building, Royal Children's Hospital, Herston Road, Herston, QLD 4029, Australia. (Email: [email protected])
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Summary

Influenza and pertussis are the two most common vaccine-preventable infections notified in Australia. We assessed the role of polymerase chain reaction (PCR) diagnosis in influenza and pertussis cases notified to the Australian National Notifiable Diseases Surveillance System (NNDSS). There were a total of 2 10 786 notified influenza cases (2001–2013) and 2 55 866 notified pertussis cases (1991–2013). After 1 January 2007, the majority of influenza and pertussis notifications were PCR-based (80·5% and 59·6%, respectively). Before 31 December 2006, PCR-based notifications were limited (29·1% and 11·7%, respectively). By 2013, PCR-based notifications had largely replaced all other diagnostic methods, with the exception of serology-based notifications in pertussis cases in adults aged ⩾25 years.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2015 

INTRODUCTION

Influenza and pertussis are the two most common vaccine-preventable infections notified in Australia [1]. The clinical illness for both influenza and pertussis infections range from mild to severe, and asymptomatic cases can occur across all age groups, and may not be uncommon [Reference Fraaij and Heikkinen2, Reference Ward3].

Both influenza and pertussis are nationally notifiable in Australia according to State and Territory legislation. For notification, cases must meet the case definitions which require laboratory evidence of infection, with acceptable testing methods including polymerase chain reaction (PCR), culture, antigen detection, and serology [4, 5].

Compared to culture and serology, PCR testing is more sensitive and has a faster turn-around time for results [Reference Fry6]. In Australia, the availability of PCR for diagnosis of influenza and pertussis has increased over the last decade. Public funding for laboratories to test specimens using PCR commenced under the Australian Government-funded Medicare Benefits Schedule in 2005 [7]. Additionally, public funding was provided for laboratories to purchase equipment, primarily for PCR, during the 2009 H1N1 influenza pandemic [8].

Since 2007, increased influenza and pertussis incidence has been associated with a pertussis epidemic (2009–2012) caused in part by waning immunity, and an influenza pandemic (2009) caused by the circulation of a novel virus strain [1, Reference Sheridan9]. The role of improved availability of PCR testing has been hypothesized to have led to improved case ascertainment and improved detection of disease activity [1, Reference Kaczmarek10].

With this study, we describe patterns of notified pertussis and influenza cases in Australia, and explore the role of newer laboratory diagnostic methods in any changes.

METHODS

All available pertussis and influenza notifications were obtained from the National Notifiable Diseases Surveillance System (NNDSS). Both are notifiable conditions under Public Health legislation in each State and Territory in Australia, and all cases that meet the case definition are required to be notified to the State and Territory Health Departments [5]. The Australian Government Department of Health aggregates state notification data in the NNDSS.

Influenza has been nationally notifiable since 2001 and a confirmed case of influenza requires a laboratory diagnosis. Definitive laboratory evidence for notification consists of isolation of influenza virus by culture, detection of influenza virus by nucleic acid testing, or laboratory detection of influenza virus antigen. Alternatively, serology for notification requires IgG seroconversion, a significant increase in antibody level or a ⩾fourfold rise in titre to influenza virus, or a single high titre by complement fixation testing or haemagglutination inhibition assay to influenza virus [5].

Pertussis was made nationally notifiable in 1991, and a case meets the definition if there is either laboratory definitive evidence or a combination of laboratory suggestive evidence with clinical evidence. Laboratory definitive evidence includes isolation of Bordetella pertussis by culture, detection of B. pertussis by nucleic acid testing, or seroconversion in paired sera for B. pertussis using whole cell or specific B. pertussis antigen(s) in absence of recent pertussis vaccination. Laboratory suggestive evidence required for notification, in absence of recent vaccination, includes a significant change (increase or decrease) in antibody level (IgG, IgA) to B. pertussis whole cell or B. pertussis specific antigen(s), or a single high IgG and/or IgA titre to pertussis toxin, or a single high IgA titre to whole cell B. pertussis antigen. Clinical evidence requires coughing illness lasting ⩾2 weeks or paroxysms of coughing, inspiratory whoop or post-tussive vomiting [4].

Line listed data were provided for each notification, rather than each individual case, as cases could be notified in duplicate following different diagnostic tests. Duplicate notifications, where a case was diagnosed using more than one diagnostic method and therefore notified more than once, were combined into a single record. Notifications with laboratory testing methods of histopathology, microscopy, ‘other’ or ‘unknown’ were excluded, as the former two no longer meet the case definition and it is uncertain whether the latter two meet the case definition. During analysis, data were aggregated by diagnostic method, year and age groups (<1, 1 to <5, 5 to <10, 10 to <15, 15 to <25, ⩾25 years). Annual age-group specific incidence rates per 1 00 000 population were calculated using Australian Bureau of Statistics population estimates [11]. For simplicity, duplicate notifications were grouped into ‘Multiple methods (PCR)’ if PCR was one of the diagnostic methods used, or ‘Multiple methods (other)’ if any combination of tests not including PCR were used. Data were also aggregated into the pre-PCR era (⩽31 December 2006) and PCR era (⩾1 January 2007). Although funding became available in late 2005 for PCR testing [7], the PCR era was defined as beginning 1 January 2007 as it took time for laboratories to purchase equipment and liaise with clinicians to change sample collection protocols. Total PCR-based notifications (PCR-only notifications combined with duplicate notifications where PCR was one of the methods used) were compared with all other single and duplicate non-PCR notifications (‘All non-PCR methods’).

Ethics approvals for this study were obtained from the ACT Health Human Research Ethics Committee and The University of Queensland School of Population Health Research Ethics Committee.

RESULTS

A total of 2 10 786 influenza cases and 2 55 866 pertussis cases were notified over the study period (influenza: 1 January 2001 to 31 December 2013; pertussis: 1 January 1991 to 31 December 2013). Of these, 12 666 (6·0%) influenza and 64 438 (25·2%) pertussis notifications were excluded, predominantly because they had an ‘unknown’ diagnosis method (85·5% and 99·4%, respectively (Table 1). Excluded notifications were approximately equally distributed across all age groups but primarily occurred in the pre-PCR era rather than the PCR era (influenza: 18·8% vs. 4·8%; pertussis: 48·2% vs. 25·2%, respectively). The majority of influenza and pertussis cases were notified following a single diagnostic test (92·8% and 98·0%, respectively). From 2007 (the ‘PCR era’), the majority of influenza and pertussis notifications were PCR-based (80·5% and 59·6%, respectively), with serology largely responsible for the remainder of notifications (12·3% and 39·9%, respectively).

Table 1. Influenza and pertussis notifications, by diagnostic method and time period, to 31 December 2013, Australia

* Includes all notifications where polymerase chain reaction (PCR) was used in combination with culture, serology and/or antigen detection.

Includes any combination of culture, serology and/or antigen detection-based notifications, without PCR testing.

Includes all ‘PCR only’ and ‘Multiple methods: PCR’ notifications.

§ Excluded notifications include those with a laboratory method of histopathology, microscopy, ‘other’ or ‘unknown’.

There was variation in the median age of notifications, with individuals whose notification was based on PCR methods consistently younger than individuals whose notification was based on non-PCR methods (Table 2). The age difference between individuals with PCR and non-PCR-based notifications increased in the PCR era for both influenza and pertussis cases. The incidence rate of influenza and pertussis notifications (per 100 000 age group-specific population) increased in all age groups (Figs 1 and 2).

Fig. 1. Annual influenza notification rate per 1 00 000 age-specific population, 1 January 2001 to 31 December 2013, Australia.

Fig. 2. Annual pertussis notification rate per 1 00 000 age-specific population, 1 January 2001 to 31 December 2013, Australia.

Table 2. Median and mean age of influenza and pertussis notifications, by diagnostic method and time period, to 31 December 2013*, Australia

PCR, Polymerase chain reaction.

* Influenza reporting period: 1 January 2001 to 31 December 2013; pertussis reporting period: 1 January 1991 to 31 December 2013.

‘PCR’ includes all notifications where PCR was used as diagnostic method (irrespective of whether the sole method or in combination with other methods).

‘All non-PCR methods’ includes all culture, serology and/or antigen detection-based notifications, including any combination of these diagnostic methods, without PCR testing.

Between the pre-PCR era and PCR era there was a 3·1-fold increase [95% confidence interval (CI) 3·0–3·1] in the proportion of influenza PCR-based notifications and an 8·7-fold increase (95% CI 8·5–9·0) in the proportion of pertussis PCR-based notifications (Table 3). The proportion of all non-PCR-based notifications decreased 0·4-fold for influenza notifications and 0·5-fold for pertussis notifications. The highest increases in the proportion of PCR-based notifications were in children aged 1 to <5 years (influenza) and 5 to <10 years (pertussis).

Table 3. Influenza and pertussis notifications, by age group, diagnostic method and time period, to 31 December 2013, Australia

PCR, Polymerase chain reaction; CI, confidence interval.

* Comparison between ⩽31 December 2006 and ⩾1 January 2007

‘PCR’ includes all notifications where PCR was used as diagnostic method (irrespective of whether the sole method or one of a combination).

‘All non-PCR methods’ includes all culture, serology and/or antigen detection-based notifications, including and combination of these diagnostic methods, without PCR tests.

Diagnostic methods varied by age group over the study period (Figs 3 and 4). From 2001, there was a gradual increase in the proportion of PCR-based notifications in all age groups; however, from 2007 a marked increase was observed in all age groups for influenza and younger age groups (<15 years) for pertussis. Although the proportion of PCR-based pertussis notifications also increased in individuals aged ⩾15 years, a large proportion of notifications in the 15 to <25 and ⩾25 years age groups remained serology-based in the PCR era. The proportion of culture, serology and antigen detection-based notifications in influenza cases and younger pertussis cases declined over the study period.

Fig. 3. Notifications of influenza by diagnostic method and year, 1 January 2001 to 31 December 2013, Australia, with percent of notifications on the left axis and total number of notifications on the right axis.

Fig. 4. Notifications of pertussis by diagnostic method and year, 1 January 2001 to 31 December 2013, Australia, with percent of notifications on the left axis and total number of notifications on the right axis.

DISCUSSION

PCR-based influenza and pertussis notifications have increased substantially in Australia over the study period. In the PCR era (⩾2007), the proportion of notifications that were PCR-based for influenza and pertussis was 3·1- and 8·7-fold higher, respectively, compared to the pre-PCR era. The largest increase in the proportion of PCR-based notifications was in children aged 5 to <10 years. By 2013, the majority of notifications were PCR-based and PCR had largely replaced all other diagnostic methods, other than in pertussis cases aged ⩾25 years, which remain predominantly serology-based (68·5% in 2013).

PCR has provided an opportunity to increase testing due to its advantages over previously available diagnostic methods. In Australia in the pre-PCR era, culture, antigen detection, and serology were the primary methods for diagnosing influenza and pertussis. Serology is generally rejected for younger age groups who are more likely to present during acute illness, and has primarily been (and continues to be) used in older age groups for retrospective diagnosis, especially for pertussis [Reference Sintchenko12, Reference Harper13]. Culture and antigen detection can be used during acute illness; however, both of these methods have limitations. Culture (particularly for pertussis) requires high-quality specimens, is time consuming, difficult, costly, and has been increasingly rarely offered over time [Reference Sintchenko12Reference Dwyer14]. Antigen detection is generally not available for pertussis, while for influenza, it has lower sensitivity than culture or PCR, is not routinely used in Australia, and can be expensive [Reference Dwyer14]. By contrast, PCR provides highly sensitive and specific, rapid, inexpensive diagnostic testing, with fewer specimen collection, quality or transport requirements [Reference Sintchenko12, Reference Dwyer14]. It is therefore not surprising that the use of PCR has increased markedly over time, or that it has replaced other diagnostic methods.

The expansion of PCR-based testing and the impact on notifications seen in our study may, at least in part, explain changes in the observed epidemiology of pertussis and influenza that occurred over the study period. In the pre-PCR era, both pertussis and influenza had different age distributions, with incidence rates highest in very young children [Reference Begg15]. During the PCR era, a growing proportion of notifications have occurred in older children [1]. Our results highlight that PCR has provided the opportunity to test and notify cases in age groups (particularly 5 to <10 years) that have previously had low notification rates. Increasing incidence of influenza and pertussis notifications may also be partially attributed to changes in diagnostics, with PCR providing the opportunity to test more broadly. Previous Australian studies have observed an increase in the total number of pertussis and influenza diagnostic tests performed since 2007, and a sevenfold rise in the likelihood of having a pertussis diagnostic test ordered in the primary-care setting between 2000–2004 and 2010–2011 [Reference Kaczmarek10, Reference Lambert16].

However, expanding availability and use of PCR did not occur in isolation, and there are other factors that are likely to have contributed to increased PCR-based notifications. In recent years, Australia has experienced a pertussis epidemic (2009–2012) and influenza pandemic (2009) [1]. The pertussis epidemic has in part been attributed to waning immunity in older children who received complete courses of acellular vaccine, while the impact of the influenza pandemic was due to a novel strain to which children and younger adults were more susceptible [1, Reference Sheridan9]. While the pathogen–host interactions were responsible for changes in incidence and demographics, we argue that without the increased availability of PCR, it would have been more difficult to detect these changes. Additionally, there was substantial media attention about pertussis and influenza during peak periods of activity and following deaths in young infants. Improved awareness, whether following media attention or training, has been found to increase diagnostic testing, through changed patient and clinician behaviour [Reference Kenyon17Reference Zhang20]. Moreover, the combination of improved PCR availability, better awareness and increased circulation of pathogens is likely to have created a positive feedback loop, ultimately leading to more testing over time.

Overall, increasing PCR use has probably improved case detection for notifiable infections such as influenza and pertussis. The purpose of infectious disease surveillance is to monitor trends, detect outbreaks, and both guide and evaluate public health responses. While at a national level the NNDSS functions very well to achieve these goals, as a passive surveillance system it is prone to case under-ascertainment and has lower sensitivity than an active surveillance system. Over our study period, the changes in the use of PCR, along with increased awareness of the illnesses, would have improved NNDSS case ascertainment, sensitivity, and representativeness. There would also have been a reduction in ascertainment bias, as PCR allows more widespread testing (and therefore notification) of cases across the population. Although it is unlikely that PCR use will decline in the near future, we hypothesize that the increase in testing will eventually plateau and set a new higher background incidence for pertussis and influenza. At this time it will be easier to identify true increases in incidence without the influence of changes in testing and awareness.

We have demonstrated the role that increased PCR use has had on observed pertussis and influenza epidemiology; however, this phenomenon is not limited to Australia. Globally, other countries with increasing PCR use have reported similar changes to observed pertussis incidence and demographics [Reference Cherry21, Reference Fisman22]. As PCR testing is expanded to other pathogens, such as those that cause gastrointestinal infections [Reference de Boer23, Reference Liu24], changes to the infection epidemiology are likely to be observed. When relying on a laboratory-based surveillance system, any changes in disease epidemiology need to be interpreted in conjunction with knowledge of underlying testing patterns.

CONCLUSION

In Australia, PCR-based influenza and pertussis notifications have been increasing since 2001 across all age groups. By 2013, PCR-based notifications had largely replaced all other diagnostic methods, with the exception of serology-based notifications in older pertussis cases.

ACKNOWLEDGEMENTS

We thank the Australian Commonwealth Government Department of Health for provision of NNDSS data used in this study. This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors.

Ms. Kaczmarek is the recipient of a Sidney Myer Health Scholarship and receives student support from the Queensland Children's Medical Research Institute and The University of Queensland School of Public Health. Associate Professor Lambert is supported by an Early Career Fellowship from the Australian Government National Health and Medical Research Council and a people support grant from the Queensland Children's Hospital Foundation.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. NNDSS Annual Report Writing Group. Australia's notifiable disease status, 2011: Annual report of the National Notifiable Diseases Surveillance System. Communicable Diseases Intelligence 2013; 37: E313E393.Google Scholar
2. Fraaij, PL, Heikkinen, T. Seasonal influenza: the burden of disease in children. Vaccine 2011; 29: 75247528.Google Scholar
3. Ward, JI, et al. Bordetella pertussis infections in vaccinated and unvaccinated adolescents and adults, as assessed in a national prospective randomized Acellular Pertussis Vaccine Trial (APERT). Clinical Infectious Diseases 2006; 43: 151157.Google Scholar
4. Australian Government Department of Health. Australian national notifiable diseases case definitions: pertussis case definition, 2004. (http://www.health.gov.au/internet/main/publishing.nsf/Content/cda-surveil-nndss-casedefs-cd_pertus.htm). Accessed August 2014.Google Scholar
5. Australian Government Department of Health. Australian national notifiable diseases case definitions: influenza case definition, 2008. (http://www.health.gov.au/internet/main/publishing.nsf/Content/cda-surveil-nndss-casedefs-cd_flu.htm). Accessed September 2014.Google Scholar
6. Fry, NK, et al. Role of PCR in the diagnosis of pertussis infection in infants: 5 years' experience of provision of a same-day real-time PCR service in England and Wales from 2002 to 2007. Journal of Medical Microbiology 2009; 58: 10231029.Google Scholar
7. Australian Government Department of Health and Ageing. Medicare Benefits Schedule Book: Operating from 1 November 2005. Canberra: Commonwealth of Australia, 2005.Google Scholar
8. Australian Government Department of Health and Ageing. Review of Australia's Health Sector Response to Pandemic (H1N1) 2009: lessons identified. Canberra: Commonwealth of Australia, 2011.Google Scholar
9. Sheridan, SL, et al. Waning vaccine immunity in teenagers primed with whole cell and acellular pertussis vaccine: recent epidemiology. Expert Review of Vaccines 2014; 13: 10811106.Google Scholar
10. Kaczmarek, MC, et al. Sevenfold rise in likelihood of pertussis test requests in a stable set of Australian general practice encounters, 2000–2011. Medical Journal of Australia 2013; 198: 624628.Google Scholar
11. Australian Bureau of Statistics. 3101·0 – Australian demographic statistics. December 2013 (http://www.abs.gov.au/AUSSTATS/[email protected]/DetailsPage/3101.0Dec%202013?OpenDocument). Accessed July 2014.Google Scholar
12. Sintchenko, V. The re-emergence of pertussis: implications for diagnosis and surveillance. New South Wales Public Health Bulletin 2008; 19: 143145.Google Scholar
13. Harper, SA, et al. Seasonal influenza in adults and children – diagnosis, treatment, chemoprophylaxis, and institutional outbreak management: clinical practice guidelines of the Infectious Diseases Society of America. Clinical Infectious Diseases 2009; 48: 10031032.Google Scholar
14. Dwyer, DE, et al. Laboratory diagnosis of human seasonal and pandemic influenza virus infection. Medical Journal of Australia 2006; 185 (10 Suppl.): S4853.Google Scholar
15. Begg, K, et al. Australia's notifiable diseases status, 2006: Annual Report of the National Notifiable Diseases Surveillance System. Communicable Diseases Intelligence 2008; 32: 139207.Google ScholarPubMed
16. Lambert, SB, et al. Influenza surveillance in Australia: we need to do more than count. Medical Journal of Australia 2010; 193: 4345.Google Scholar
17. Kenyon, C, et al. Assessing the impact of a pertussis active surveillance program on provider testing behavior, Minnesota 2005–2009. American Journal of Public Health 2014; 104: e3439.Google Scholar
18. Sharma, V, et al. Influence of the news media on diagnostic testing in the emergency department. Archives of Pediatrics & Adolescent Medicine 2003; 157: 257260.Google Scholar
19. Grilli, R, et al. Mass media interventions: effects on health services utilisation. Cochrane Database of Systematic Reviews 2002. Issue 1. Art no. CD000389.Google Scholar
20. Zhang, Y, et al. Characterizing Influenza surveillance systems performance: application of a Bayesian hierarchical statistical model to Hong Kong surveillance data. BMC Public Health 2014; 14: 850.Google Scholar
21. Cherry, JD. Epidemic pertussis in 2012 – the resurgence of a vaccine-preventable disease. New England Journal of Medicine 2012; 367: 785787.Google Scholar
22. Fisman, DN, et al. Pertussis resurgence in Toronto, Canada: a population-based study including test-incidence feedback modeling. BMC Public Health 2011; 11: 694.Google Scholar
23. de Boer, RF, et al. Detection of Campylobacter species and Arcobacter butzleri in stool samples by use of real-time multiplex PCR. Journal of Clinical Microbiology 2013; 51: 253259.Google Scholar
24. Liu, J, et al. Simultaneous detection of six diarrhea-causing bacterial pathogens with an in-house pcr-luminex assay. Journal of Clinical Microbiology 2012; 50: 98103.Google Scholar
Figure 0

Table 1. Influenza and pertussis notifications, by diagnostic method and time period, to 31 December 2013, Australia

Figure 1

Fig. 1. Annual influenza notification rate per 1 00 000 age-specific population, 1 January 2001 to 31 December 2013, Australia.

Figure 2

Fig. 2. Annual pertussis notification rate per 1 00 000 age-specific population, 1 January 2001 to 31 December 2013, Australia.

Figure 3

Table 2. Median and mean age of influenza and pertussis notifications, by diagnostic method and time period, to 31 December 2013*, Australia

Figure 4

Table 3. Influenza and pertussis notifications, by age group, diagnostic method and time period, to 31 December 2013, Australia

Figure 5

Fig. 3. Notifications of influenza by diagnostic method and year, 1 January 2001 to 31 December 2013, Australia, with percent of notifications on the left axis and total number of notifications on the right axis.

Figure 6

Fig. 4. Notifications of pertussis by diagnostic method and year, 1 January 2001 to 31 December 2013, Australia, with percent of notifications on the left axis and total number of notifications on the right axis.