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Prevalence and incidence of emergency department presentations and hospital separations with injecting-related infections in a longitudinal cohort of people who inject drugs

Published online by Cambridge University Press:  13 November 2023

Stephanie J. Curtis Open the ORCID record for Stephanie J. Curtis [Opens in a new window] ,
Samantha Colledge-Frisby ,
Andrew J. Stewardson ,
Joseph S. Doyle ,
Peter Higgs ,
Lisa Maher ,
Matthew Hickman ,
Mark A. Stoové  and
Paul M. Dietze
Stephanie J. Curtis*
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia Department of Infectious Diseases, the Alfred Hospital and Central Clinical School, Monash University, Melbourne, VIC, Australia
Samantha Colledge-Frisby
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia National Drug Research Institute, Curtin University, Melbourne, VIC, Australia
Andrew J. Stewardson
Affiliation:
Department of Infectious Diseases, the Alfred Hospital and Central Clinical School, Monash University, Melbourne, VIC, Australia
Joseph S. Doyle
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia Department of Infectious Diseases, the Alfred Hospital and Central Clinical School, Monash University, Melbourne, VIC, Australia
Peter Higgs
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia Department of Public Health, La Trobe University, Bundoora, VIC, Australia
Lisa Maher
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia The Kirby Institute, Faculty of Medicine, UNSW, Wallace Wurth Building, Kensington, NSW, Australia
Matthew Hickman
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia Population Health Sciences, Bristol Medical School, University of Bristol, Bristol, UK
Mark A. Stoové
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia The Kirby Institute, Faculty of Medicine, UNSW, Wallace Wurth Building, Kensington, NSW, Australia School of Public Health and Preventive Medicine, Monash University, Melbourne, VIC, Australia
Paul M. Dietze
Affiliation:
Disease Elimination Program, Burnet Institute, Melbourne, VIC, Australia National Drug Research Institute, Curtin University, Melbourne, VIC, Australia School of Public Health and Preventive Medicine, Monash University, Melbourne, VIC, Australia
*
Corresponding author: Stephanie J. Curtis; Email: stephanie.curtis@monash.edu
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Abstract

People who inject drugs are at risk of acute bacterial and fungal injecting-related infections. There is evidence that incidence of hospitalizations for injecting-related infections are increasing in several countries, but little is known at an individual level. We aimed to examine injecting-related infections in a linked longitudinal cohort of people who inject drugs in Melbourne, Australia. A retrospective descriptive analysis was conducted to estimate the prevalence and incidence of injecting-related infections using administrative emergency department and hospital separation datasets linked to the SuperMIX cohort, from 2008 to 2018. Over the study period, 33% (95%CI: 31–36%) of participants presented to emergency department with any injecting-related infections and 27% (95%CI: 25–30%) were admitted to hospital. Of 1,044 emergency department presentations and 740 hospital separations, skin and soft tissue infections were most common, 88% and 76%, respectively. From 2008 to 2018, there was a substantial increase in emergency department presentations and hospital separations with any injecting-related infections, 48 to 135 per 1,000 person-years, and 18 to 102 per 1,000 person-years, respectively. The results emphasize that injecting-related infections are increasing, and that new models of care are needed to help prevent and facilitate early detection of superficial infection to avoid potentially life-threatening severe infections.

Keywords

bloodstream infectionendocarditishospitalizationskin and soft tissue infectionssubstance-related disorders
Type
Original Paper
Information
Epidemiology & Infection , Volume 151 , 2023 , e192
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Background

Injecting-related infections (IRIs) are a clinical complication of injection drug use. IRIs among people who inject drugs are most commonly localized skin and soft tissue infections (SSTI), or can be more invasive systemic infections, such as bacteraemia, osteomyelitis, and endocarditis [Reference Hope1]. SSTI can often be managed in primary care; however, if initial treatment is delayed, acute treatment in the emergency department (ED) may be required [Reference Larney2, Reference Hope3]. Invasive infections usually require hospital care and can result in lengthy hospital stays for complex surgical intervention and prolonged intravenous antibiotic therapy [Reference Hope1, Reference Magsino4]. IRIs account for a high burden of disease and a substantial proportion of the total hospitalizations of people who inject drugs, and there is evidence that hospitalizations for all types of IRI are increasing globally [Reference Valerio5Reference Curtis13].

There are few estimates of the incidence of IRIs among people who inject drugs, with empirical evidence of IRIs in this group restricted largely to prevalence estimates from people engaged in drug treatment or self-report data [Reference Lewer11, Reference Colledge-Frisby12]. A systematic review estimated a varied lifetime prevalence of IRI in people who inject drugs; SSTI (6–69%), sepsis/septicaemia (2–10%), infective endocarditis (0.5–12%), and bone and joint infections (0.5–2%) [Reference Larney2]. In a recent survey of people who inject drugs in Victoria, Australia, 24% self-reported having an injection-related health issue in the preceding month, including 7% reporting infection and/or abscess [Reference Wilson14]. However, as indicated, most estimates are derived from self-reported data and validity of estimates may be questioned in the absence of clinical confirmation of these infections [Reference Larney2].

Hospitalization data, typically coded using International Classification of Diseases (ICD) codes, can be used to ascertain the incidence of IRIs requiring clinical care that are likely related to injecting drug use [Reference Colledge-Frisby12]. In Australia, incidence estimates of hospital separations with an IRI are limited to a cohort of people with a history of opioid agonist treatment in New South Wales (43 per 1,000 person-years between 2001 to 2017) and a cohort identified by an algorithm of ICD, Tenth Revision, Australian Modification (ICD-10-AM) codes at a Melbourne health service (192 per 100,000 annual hospital admissions between 2008 and 2018) [Reference Colledge-Frisby12, Reference Curtis13]. International incidence estimates of hospital separations with an IRI are also limited to a cohort of people who injected heroin entering community-based substance use treatment in South London (73 per 1,000 person-years between 2006 and 2017) [Reference Lewer11] and people who inject drugs with problematic alcohol use in a Swedish Prison and Probation Service (SSTI, 28.3 per 1,000 person-years and systemic bacterial infection, 9.1 per 1,000 person-years between 2001 and 2014) [Reference Dahlman15]. People who inject drugs with a history of opioid agonist treatment are not necessarily representative of the broader community of people who inject drugs; approximately half of people who inject drugs have engaged in opioid agonist treatment in their lifetime in Australia [Reference Heard, Iversen and Maher16]. Additionally, cohorts of people who inject drugs engaged in opioid agonist treatment are likely to underestimate the incidence of hospitalizations as they are likely to inject less frequently compared to those not engaged in opioid agonist treatment and are likely to be more engaged with healthcare services which may be protective of infection [Reference Mittal17].

Overall, there is limited evidence on IRI incidence among people who inject drugs and despite evidence that IRIs are an increasing issue for people who inject drugs, few have investigated incidence of infections among a community cohort of people who inject drugs. In this study, we address this gap by examining the incidence and period prevalence of ED presentations and hospital separations related to IRI in a cohort of people who inject drugs in Melbourne, Australia.

Methods

Study design

We performed a descriptive analysis of a prospective observational cohort linked to administrative health data from 2008 to 2018. The full details of the cohort study, the Melbourne Injecting Drug User Cohort Study (SuperMIX), can be found elsewhere [Reference Van Den Boom18, Reference Horyniak19].

Setting and participants

A total of 1,288 SuperMIX participants were included who resided in Melbourne metropolitan or the Greater Geelong region, Victoria, Australia. Participants were aged 18 or over, held a valid Australian universal healthcare insurance (Medicare) number, and injected either heroin or methamphetamine at least monthly over the six months prior to baseline recruitment. Participants were recruited through a combination of respondent-driven sampling, snowball sampling, and street-based outreach methods in multiple recruitment waves between January 2008 and July 2019. Primary data collection included socio-demographics (e.g., age, sex, country of birth, Aboriginal and Torres Strait Islander status, employment status, education, housing, and history of incarceration), drug behaviours (e.g., age at first injection, type, and frequency of drug use), and health-related characteristics (e.g., health service utilization, interactions with criminal justice systems and validated well-being assessment tools). Participants completed optional annual follow-up surveys following recruitment to further capture socio-demographics, drug behaviours, and health-related characteristics [Reference Nambiar20, Reference Di Rico21].

Data sources

Primary cohort data were linked to state-wide hospital data from the Victorian Emergency Minimum Dataset and Victorian Admitted Episode Dataset, and data on all deaths in Australia from the National Death Index. The Victorian Emergency Minimum Dataset details administrative and clinical data on ED presentations to Victorian public hospitals. The Victorian Admitted Episode Dataset details administrative and clinical data on hospital separations at Victorian public and private hospitals, including ‘hospital in the home’ (admitted acute care provided to patients in their own home, or other suitable environment outside hospital). ICD-10-AM codes are used to code up to three diagnoses per ED presentation in the Victorian Emergency Minimum Dataset and up to 39 diagnoses per hospital separation in the Victorian Admitted Episode Dataset. The National Death Index collates information on cause (ICD-10-AM) and date of death in Australia and was used to determine all-cause mortality following ED presentation or hospital admission and to censor participants when calculating person-years. Data were linked through deterministic linkage as described elsewhere [Reference Nambiar20], and all participants had consented to retrospective data linkage before their enrolment date to allow for linkage from 1 January 2008 onwards, regardless of the participants’ age at the time of ED presentation or hospital separation. Although this is a prospective observational cohort, data linkage from 2019 onwards was not yet available at the time of analysis.

Outcome variables

ED presentations and hospital separations with an IRI were the outcomes, identified using ICD-10-AM codes in the Victorian Emergency Minimum Dataset and Victorian Admitted Episode Dataset. The ICD-10-AM codes were selected based on a previous study of IRIs in the same setting (Supplementary Table S1) and were identified as ED presentation or hospital separations with any IRI coded (i.e., either as a primary or secondary diagnostic code) [Reference Curtis13]. In Australia, dedicated hospital staff are trained to retrospectively review clinical notes and encode ICD-10-AM data according to strict criteria for the Victorian Admitted Episode Dataset. For the Victorian Emergency Minimum Dataset, computer software is used to encode ICD-10-AM data by mapping the clinical diagnoses entered by clinicians in patient discharge documentation [Reference Di Rico21]. IRIs identified through the ICD-10-AM codes were grouped as SSTI and invasive infections (bloodstream infection/sepsis, osteomyelitis/septic arthritis, and infective endocarditis). Complicated SSTIs were defined as patients that had an invasive infection alongside a SSTI, and uncomplicated SSTIs were defined as patients with an SSTI but no invasive infection.

Additional cohort characteristics

A range of additional data were collected from the data sources. Primary cohort data collected date of birth, sex, country of birth, and Aboriginal and Torres Strait Islander status. Where primary cohort data were missing date of birth or sex, we utilized the Victorian Emergency Minimum Dataset and Victorian Admitted Episode Dataset data. The Victorian Emergency Minimum Dataset and Victorian Admitted Episode Dataset collected date of most recent prior ED presentation and hospital separation, hospital admission or discharge following ED presentation, hospital admission source (ED, transfer or planned), intensive care unit stay, and patient-directed discharge. Patient-directed discharge was defined as hospital separations coded as left against medical advice and ED presentations coded as left at own risk, either without treatment, after clinical advice regarding treatment options, or after treatment started. National Death Index data were used to collect all-cause mortality within 100 days of hospital separation.

Statistical methods

Descriptive analyses summarized cohort characteristics and the period prevalence of ED presentations and hospital separations with an IRI. Period prevalence was estimated for any IRI and each IRI for both ED presentations and hospital separations, calculated by dividing the number of participants who had at least one ED presentation or hospital separation with an IRI by the total number of participants from 2008 to 2018. Individuals who had multiple IRIs were captured across each IRI prevalence estimate, regardless of whether the IRI occurred in the same hospital separation episode.

The start of follow-up was the participant’s self-report initiation of injecting drug use or 1 January 2008, whichever came last. In the cohort study’s annual follow-up surveys, participants reported dates of injecting drug use cessation and resumption, if applicable. Therefore, the end of follow-up was the participant’s date of death, self-report cessation of injecting drug use without resumption reported in a subsequent follow-up survey, or 31 December 2018, whichever came first. Overall and annual incidence were calculated by dividing the number of ED presentations and hospital separations for each IRI and any IRI by the number of person-years in the cohort during the specified period (expressed as IRI events per 1,000 person-years). Individuals who had multiple IRIs within one hospital separation were captured across each IRI incidence estimate.

We also excluded individuals’ person-time follow-up period where injecting drug use ceased for 12 months or longer; therefore, ED presentations and hospital separations with an IRI during this period were excluded. As our analysis was a count of event over person-time, individuals were not censored after an IRI event unless they died or ceased injecting for 12 months or longer. Due to privacy requirements of the data custodian, we were unable to report central nervous system and deep abscess IRIs, annual ED presentations stratified by SSTI and invasive infection, or inpatient mortality with an IRI. All the statistical analyses were performed by using R version 4.05 [22].

Results

Participants

Among 1,288 participants, 427 people (33%) presented to ED with ≥1 IRI (1,044 ED presentations in total) and 345 (27%) were admitted to hospital with ≥1 IRI (740 hospital separations in total). Most hospital separations (n = 663, 89.6%) with an IRI were reported as admitted via an ED presentation, of which only 68.2% (n = 452) were captured in the ED presentation dataset (Figure 1). Both ED presentations and hospital separations with an IRI were more commonly male, 67% and 64%, respectively, and were similar in age (median age of 32 years (interquartile range (IQR): 28–36) and 32 years (IQR: 29–36), respectively). Patient-directed discharge for patients with an IRI occurred for 7.2% (n = 75) of ED presentations and 20.5% (n = 152) of hospital separations. Characteristics of ED presentations and hospital separations with an IRI are presented in Table 1.

Figure 1. Flowchart of emergency department presentations and hospital separations with an injecting-related infection.

Table 1. Characteristics of participant hospitalizations with an injecting-related infection, by emergency department presentations and hospital separations

Abbreviations: ED, emergency department; IRI, injecting-related infection; IQR, interquartile range.

Frequency, period prevalence and incidence of ED presentation and hospital separations with IRIs

The period prevalence of any ED presentation and hospital separation involving an IRI over the observation period was 33% (95%CI: 31%–36%) and 27% (95%CI: 24%–29%), respectively (Table 2). Most ED presentations and hospital separations involved a SSTI, 89% (n = 919) and 75% (n = 552), respectively. Of 128 ED presentations involving invasive infection, most were for bloodstream infection/sepsis (n = 80, 63%), followed by osteomyelitis/septic arthritis (n = 30, 23%) and infective endocarditis (n = 18, 16%). Of 250 hospital separations involving invasive infection, most were for bloodstream infection/sepsis (n = 157, 63%), followed by osteomyelitis/septic arthritis (n = 92, 37%) and infective endocarditis (n = 80, 32%). More than one IRI was coded for 126 (18%) hospital separations.

Table 2. Frequency, period prevalence and incidence of emergency department presentations and hospital separations with an injecting-related infection

Abbreviations: CI, confidence interval; ED, emergency department; IRI, injecting-related infection; IQR, interquartile range.

From 2008 to 2018, across 13,106 person-years of follow-up (median 11 years (range 0.8–11 and IQR: 11–11); mean 10.2 years (standard deviation: 2.04) per participant), the incidence of ED presentations with an IRI was 80 per 1,000 person-years, and 56 per 1,000 person-years for hospital separations. The incidence of ED presentations involving an SSTI was 70 per 1,000 person-years and involving invasive infection was 10 per 1,000 person-years. The incidence of hospital separations involving SSTI was 42 per 1,000 person-years and involving invasive infection was 19 per 1,000 person-years. There were a total 7,159 bed-days with an IRI, and the median inpatient length of stay was 3 days (range 0–980 and IQR: 1–8).

Annual incidence of ED presentation and hospital separations with an IRI

There was a steady increase in the incidence of ED presentations and hospital separations with an IRI over time (Figures 2 and 3). From 2008 to 2018, incidence of both ED presentations and hospital separations with an IRI increased 2.8 times from 48 to 135 per 1,000 person-years and 5.7 times from 18 to 102 per 1,000 person-years, respectively. Over this period, the increase in hospital separations was observed for both SSTIs, 7.1 times from 10 to 71 per 1,000 person-years, and invasive infections, 4.3 times from 8 to 34 per 1,000 person-years. Supplementary Figures S1 and S2 present the annual number of unique participants with an IRI-related ED presentation and hospital separation, illustrating an increasing number of unique participants presenting to hospital with an IRI annually since 2008.

Figure 2. Incidence of emergency department presentations with an injecting-related infection per 1,000 person-years.

Figure 3. Incidence of hospital separations with an injecting-related infection per 1,000 person-years.

Discussion

We observed a high 11-year period prevalence and incidence of ED presentations and hospital separations with an IRI among people who inject drugs in Australia, with both ED presentations and hospital separations increasing in recent years. Over the study period, one-third of our cohort presented to an ED and over a quarter were hospitalized with an IRI, most commonly for SSTI. From 2008 to 2018, the incidence of ED presentations and hospital separations with an IRI increased substantially and patient-directed discharge was also common.

We report a high period prevalence and increasing incidence of both unique individuals and overall count of ED presentations and hospital separations with SSTI. These infections can often be managed in primary care, and hospitalization may represent delayed access to care within this cohort [Reference Islam23Reference Neale, Tompkins and Sheard25]. In Victoria, Australia, there are multiple points for intervention to prevent and treat SSTI before hospital presentation and admission, including population-specific primary care centres, that provide a range of important services including SSTI treatment [26]. These services are an important engagement point for this population who traditionally underutilize primary care services. Nevertheless, despite the existence of these services, we found an increase in SSTIs over time. We suspect that the impact of these services could be improved by increasing staffing and operating hours of existing services, and the establishment of new services. Furthermore, there is also a clear need for upstream prevention and early treatment of IRIs, particularly SSTIs, that could potentially reduce the high incidence of ED presentations and hospital separations observed in our study [Reference Sanchez27]. Prevention efforts are also required to address causes of IRIs, such as education to improve hygiene and injecting techniques, and addressing social-structural determinants that limit access to, and storage of, sterile injecting equipment and environmental hygiene, such as homelessness and poverty [Reference Ivan28, Reference Harris29].

The prevalence of hospital separations with an IRI observed in this cohort over 11 years (2008 to 2018) was similar to that in a cohort of people who injected heroin entering community-based substance use treatment in South London over 12 years (2006 to 2017); however, the overall incidence of hospital separations with an IRI was higher than observed in our study [Reference Lewer11]. We report both a higher period prevalence and incidence of hospital separations with an IRI than observed in a cohort of people with a history of opioid agonist treatment in New South Wales over 17 years (2001 to 2017) [Reference Curtis13]. Similar to a retrospective analysis of hospitalizations among patients with a diagnosis code for substance use and a serious bacterial infection in Oregon, we report that the number of unique individuals with an IRI has also been increasing in recent years [Reference Capizzi7]. In Victoria, Australia, there is consistently high needle syringe coverage and there has not been changes in injecting frequency in our cohort; therefore, the increase in unique individuals with an IRI may be due to other factors such as an ageing cohort and changes in social-structural determinants [Reference Colledge-Frisby30]. Our period prevalence estimates of invasive infections were higher than observed in South London and New South Wales [Reference Lewer11, Reference Colledge-Frisby12], which may be driven by higher engagement in health services leading to early treatment of IRIs by the cohorts engaged in drug treatment, compared to our community-recruited cohort [Reference Mittal17]. Overall, the high period prevalence of invasive IRIs reiterates that people who inject drugs are at high risk for life-threatening severe infections and that cohorts recruited from the community are at even higher risk than samples recruited from drug treatment [Reference Colledge-Frisby12, Reference Mittal17].

Hospitals have been identified as a unique risk environment for people who inject drugs as they can experience stigma, inadequate pain, and withdrawal management and isolation from social supports when admitted to hospital [Reference Pollini31, Reference McNeil32]. This may lead to patient-directed discharge, which presents a lost opportunity for care, may lead to poorer patient outcomes, including readmission and increased mortality, and increase costs to the public health system [Reference Southern, Nahvi and Arnsten33]. In our study, 21% of people were observed to patient-directed discharge which is consistent with previous estimates on patient-directed discharge in people hospitalized with an IRI (range 13–30%) [Reference Lewer11, Reference Colledge-Frisby12, Reference Langham34]. Hospital care is nearly always required for invasive infections; however, the implementation of flexible patient-centred models which focus on hospital-based harm reduction for people who inject drugs may mitigate the consequences of patient-directed discharge, such as supervised injecting services, use of nicotine replacement therapy, short-acting opioids to treat withdrawal, and opioid agonist treatment initiation [Reference Kleinman and Wakeman35, Reference Buresh36]. In addition, these hospital-based interventions can be supported by community-based clinical care such as safe discharge with oral antibiotic therapy or weekly infusions and outpatient programmes which have emerging evidence of success [Reference Marks37Reference Baddour40].

Our findings highlight the importance of early intervention in primary care to prevent hospitalization for SSTIs and for hospital-based harm reduction interventions and safe discharge into community-based clinical care to mitigate patient-directed discharge. Further efforts are required to bridge the gap between clinical care and the needs of people who inject drugs, and all interventions should be supported by strategies which are known to be effective at reducing drug-related harms including SSTI, such as needle and syringe coverage. Further investigation is required to understand the causes of increasing IRIs, risk factors for hospitalization with an IRI, and the sequalae of patients that patient-directed discharge to better understand the implications and guide future clinical practice and policy.

Limitations

This study has some limitations. First, not all acute infections may be attributable to injecting practices; however, for people who inject drugs, SSTI are consistently reported as one of the most common causes of ED presentations and hospital admissions, and invasive infections occur more frequently in this cohort compared to the general population [Reference Hope3, Reference Wilson14, Reference Nambiar20]. Second, one infection episode could be captured multiple times for those that patient-directed discharged and represented or were readmitted, and for patient with multiple IRIs coded within one hospital separation (i.e., infective endocarditis and bloodstream infection/sepsis); however, we aimed to estimate incidence of ED presentations and hospital separations with any and each IRI rather than total unique IRI episodes. Third, due to privacy requirements, aggregate counts below a threshold were unable to be reported, including central nervous system and deep abscess IRIs, annual ED presentations stratified by SSTI and invasive infection, or inpatient mortality with an IRI. Fourth, data after 2019 were not available; therefore, ongoing analysis should be explored to confirm if IRIs have continued to increase in recent years. Fifth, our study is restricted to ED presentations and hospital separations in Victoria, Australia, and does not include hospital data from other jurisdictions in Australia. Finally, there may be limitations on the generalizability of our findings outside of Victoria or internationally, as local injecting drug use and health service utilization may be specific to this area, and Australia’s universal healthcare system includes subsidized and/or free hospital care and people who inject drugs may present to hospital more regularly than in settings where hospital care is not available for free. However, people who inject drugs are often reluctant to access medical care, and a lack of universal health care in other settings may further deter this population from receiving care for life-threatening infections, as demonstrated in our cohort’s high incidence which suggests that universal health care is necessary but not sufficient.

Conclusion

We have provided novel and objective epidemiological data of ED presentation and hospital separations with an IRI in a cohort of people who inject drugs in Melbourne, Australia. Our findings are consistent with current evidence that IRI hospitalization have been increasing in recent years, and we observed the highest incidence of ED presentations and hospital separations with an IRI reported in Australia. Combined with high prevalence of patient-directed discharge in this population, findings indicate a need for better understanding of the factors driving this increase, and integrated interventions to address the burden of IRIs.

Data availability statement

All data used in this study are protected under the privacy policies of Victorian Department of Health and Human Services ‘Deed of Acknowledgment and Confidentiality’. Signed confidentiality agreements prevent us from sharing the data.

Acknowledgements

This study was made possible by the contribution of participants, the Burnet Institute’s fieldwork team, staff at the Centre for Victorian Data Linkage, and staff at the Australian Institute of Family Studies. Above all, we thank all SuperMIX participants who have, and continue to, share their story.

Author contribution

S.J.C., A.J.S., J.S.D., M.A.S., and P.M.D. conceptualized the study; S.J.C. contributed to data curation; S.J.C. participated in data curation; S.J.C. involved in investigation; S.J.C. contributed to visualization; S.J.C., A.J.S., M.A.S., and P.M.D. performed methodology; S.J.C. and P.M.D. involved in project administration; M.A.S. and P.M.D. supervised the study; P.H., L.M., M.H., M.A.S., and P.M.D. contributed to funding acquisition; S.J.C. wrote original draft; S.J.C., S.C-F., and P.M.D. involved in writing – review & editing.

Financial support

This work was supported by the Colonial Foundation Trust and the National Health and Medical Research Council (SuperMIX study, grant number 545891) and the Centre for Research Excellence into Injecting Drug Use (SuperMIX study, grant number APP1001144). The authors gratefully acknowledge the Victorian Operational Infrastructure Support Program’s support for the Burnet Institute.

Competing interest

The authors declare none.

Ethical standard

This study was approved by the Victorian Department of Human Services (now Department of Health and Human Services), Monash University Human Research Ethics Committees and AIHW Ethics Committee (HREC/16/889).

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0950268823001784.

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Figure 0

Figure 1. Flowchart of emergency department presentations and hospital separations with an injecting-related infection.

Figure 1

Table 1. Characteristics of participant hospitalizations with an injecting-related infection, by emergency department presentations and hospital separations

Figure 2

Table 2. Frequency, period prevalence and incidence of emergency department presentations and hospital separations with an injecting-related infection

Figure 3

Figure 2. Incidence of emergency department presentations with an injecting-related infection per 1,000 person-years.

Figure 4

Figure 3. Incidence of hospital separations with an injecting-related infection per 1,000 person-years.

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