Respiratory research with Māori and Pacific children living in Aotearoa, New Zealand: a systematic review and narrative synthesis
Amio Matenga-Ikihele
1 * , Jacinta Fa’alili-Fidow 1 , Dantzel Tiakia 1 , Dudley Gentles 1 , John Natua 2 , Gemma Malungahu 3 , Bernadette Tatafu 1 , Rudy Roodhouse-Hill 1 4 , Ruby Tuesday 1 , Maria Ngawati 5 , Mataroria Lyndon 6
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Abstract
Improving the respiratory health of Māori and Pacific children in Aotearoa, New Zealand is a priority. Respiratory studies over the past decade have continued to highlight the ongoing inequities among Māori and Pacific children.
This systematic review aimed to explore the characteristics of respiratory research with Māori and Pacific children (0–14 years) living in New Zealand. Research objectives were to evaluate the types of study designs used, summarise participant demographics including ethnicity and evaluate whether culturally relevant frameworks were incorporated.
Studies were located across four databases: Medline, EBSCOHost, Scopus and PubMed, from 2010 to 2022. To qualify, studies needed to include (1) Māori or (2) Pacific children aged (3) 0–14 years and (4) describe a respiratory research project conducted in New Zealand. A narrative synthesis of the studies meeting the inclusion criteria was performed.
Of the 539 studies identified, 29 met the inclusion criteria. Most studies were retrospective cohort studies with respiratory conditions focused mainly on asthma, group A streptococcus and lower respiratory tract infections. Four studies were qualitative, and only 2 of the 29 studies reported using a Kaupapa Māori framework.
Despite the increased attention to the respiratory health of Māori and Pacific children, there is a lack of research on the lived experiences of whānau and their children who endure these conditions. Few studies incorporated culturally relevant approaches. Further research that incorporates culturally responsive approaches is urgently needed to enhance ourunderstanding of Māori and Pacific child respiratory health and to advance health equity.
Keywords: children, cultural frameworks, Māori health, Pacific health, respiratory conditions.
| WHAT GAP THIS FILLS |
| What is already known: Respiratory conditions are a major public health concern in Aotearoa New Zealand, and are responsible for a large proportion of the morbidity and mortality experienced by Māori and Pacific children. |
| What this study adds: This paper provides an important overview of respiratory research that involve Māori and Pacific children living in Aotearoa New Zealand. It emphasises that more studies focusing on the needs of Māori and Pacific whānau and communities, and the use of culturally responsive approaches, are essential, ensuring that aspirations are whānau centred and tailored to their needs. |
Introduction
Improving the respiratory health of Māori and Pacific children in New Zealand is a pressing priority due to persistent inequities within these population groups. Over the past decade, multiple studies have highlighted the ongoing challenges faced by Māori and Pacific children, including high rates of ambulatory sensitive hospitalisations related to respiratory conditions. These health disparities are exacerbated by social, economic and housing inequities, as well as barriers to accessing and utilising health care services.1–9 Despite a study by Schlichting et al.7 highlighting a notable 45% decrease in hospitalisations due to childhood asthma from 2010 to 2019, disparities persist in asthma prevalence, prescription practices and hospitalisations. This underscores the need for improved respiratory health management in New Zealand.7
To effectively advance the health and well-being of Māori and Pacific communities, it is crucial to understand and value their social and lived realities. The launch of the New Zealand Respiratory Strategy – Te Hā Ora, The Breath of Life – in 2015, aimed to reduce respiratory disease and eliminate health inequities, particularly among Māori, Pacific and low-income communities, and to establish a pathway for advocacy and research, promoting collaborative partnerships among health, housing, welfare, and education stakeholders.10 Furthermore, with the enactment of the Pae Ora (Healthy Futures) Act 2022 (NZ) the key objectives of Te Pae Tata (interim New Zealand Health plan) are to improve equitable health outcomes; embed Te Tiriti O Waitangi; implement a population health approach; and to ensure a sustainable and affordable health system.11 An important key driver of these objectives is a commitment to health equity, which is essential to support good health and wellbeing for all New Zealanders, in particular for Māori and Pacific communities.11 Several frameworks can facilitate this approach within health care, such as He Korowai Oranga: Māori Health Strategy,12 Equity of Health Care for Māori. A Framework,13 Te Mana Ola: The Pacific Health Strategy14 and the All of Government Pacific Wellbeing Strategy.15 Incorporating Kaupapa Māori and Pacific approaches like talanoa and talanga can further reinforce culturally meaningful engagement and conversations based on respect, relationships, reciprocity and trust.16–18 Importantly, when research is undertaken where Māori have equal benefits and rights as non-Māori in accordance with Te Tiriti O Waitangi, all New Zealanders benefit from this.19
In light of the persistent respiratory health disparities among Māori and Pacific children in New Zealand, the aim of this systematic review is to explore the characteristics of respiratory research conducted within this population. By exploring the existing body of literature, this review seeks to identify opportunities for improving respiratory health outcomes.
Methods
This systematic review was informed by the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) reporting guidelines.20 A protocol for the study was written and agreed upon by all co-authors before commencing (available on request from the corresponding author).
Eligibility criteria
The search and screening process identified 29 eligible papers published between 2010 and 2022. Studies were eligible to be included if they investigated any respiratory condition among Māori and Pacific children aged 0–14 in New Zealand.
Search strategy
The initial search strategy was first carried out in June 2020 and repeated in December 2022. Databases searched included Medline, EBSCOHost, Scopus and PubMed. The search strategy used in Medline is provided in Table 1. A combination of controlled vocabulary and Boolean-paired keywords were used, relating to (1) respiratory conditions, (2) Māori or (3) Pacific population group. The keywords, synonyms and various spellings were reviewed and agreed upon by all co-authors before commencement. The authors also conducted a hand search by examining the bibliographies of selected studies for other relevant citations.
| Search terms | ||
|---|---|---|
| 1 | ‘Pacific Islanders’.mp. | |
| 2 | Pacific.mp | |
| 3 | ‘Pacific people’.mp | |
| 4 | Pacific.mp. | |
| 5 | Pasefika.mp. | |
| 6 | ‘Pan Pacific’.mp | |
| 7 | Pacifica.mp. | |
| 8 | Polynesian.mp. | |
| 9 | Micronesian.mp. | |
| 10 | Melanesian.mp. | |
| 11 | Samoan.mp | |
| 12 | Tongan.mp. | |
| 13 | ‘Cook Islanders’.mp. | |
| 14 | Niuean.mp. | |
| 15 | Tuvaluan.mp. | |
| 16 | Tokelauan.mp. | |
| 17 | Fijian.mp. | |
| 18 | Kiribati*.mp. | |
| 19 | ‘Native Hawaiian’.mp. | |
| 20 | Tahitian.mp. | |
| 21 | Palauan.mp. | |
| 22 | Nauruan.mp. | |
| 23 | Futunans.mp. | |
| 24 | ‘Papua New Guinea’.mp. | |
| 25 | ‘Solomon Islands’.mp. | |
| 26 | Rotumans.mp. | |
| 27 | Vanuatuan.mp. | |
| 28 | ‘French Polynesia’.mp. | |
| 29 | Maori.mp. | |
| 30 | 1 or 2 or 3 or 4 or 5 or 6 or 7 or 8 or 9 or 10 or 11 or 12 or 13 or 14 or 15 or 16 or 17 or 18 or 19 or 20 or 21 or 22 or 23 or 24 or 25 or 26 or 27 or 28 or 29 | |
| 31 | Asthma | |
| 32 | Asthmas.mp. | |
| 33 | bronch*.mp. | |
| 34 | ‘Upper respiratory tract infection’.mp | |
| 35 | ‘Lower respiratory tract infection’.mp. | |
| 36 | pneum*.mp. | |
| 37 | nasoph*.mp. | |
| 38 | sinus*.mp. | |
| 39 | epiglot*.mp. | |
| 40 | pharyng*.mp. | |
| 41 | influenza.mp. | |
| 42 | corona*.mp. | |
| 43 | Covid.mp | |
| 44 | laryng*.mp. | |
| 45 | trach*.mp. | |
| 46 | tonsil*.mp. | |
| 47 | Tuberculosis/or tuberculosis.mp. | |
| 48 | ‘Chronic obstructive pulmonary disease’.mp. | |
| 49 | 31 or 32 or 33 or 34 or 35 or 36 or 37 or 38 or 39 or 40 or 41 or 42 or 43 or 44 or 45 or 46 or 47 or 48 | |
| 50 | 30 and 49 | |
| 51 | limit 51 to (English language and full text and humans and yr = ‘2010–Current’) |
Study selection
All articles were imported into RefWorks ProQuest software and duplicate records were removed. Studies were excluded if they were not in English, lacked full text or were conference abstracts, grey literature or not primary research. A search period of 12 years (2010–2022) was used. The quality of studies was assessed using the Joanna Briggs Institute (JBI) Critical Appraisal Checklist, which evaluates the methodological quality of quantitative and qualitative studies.21 Multiple authors (A. M. I., D. T., D. G., J. N., B. T. and R. H.) independently reviewed the titles and abstracts of the articles for inclusion or exclusion, and further crosschecking and consensus among co-authors were conducted to make the final decisions.
Data extraction
Using the PRISMA checklist, data were extracted from eligible studies into an electronic spreadsheet. The study information extracted comprised authors, year of publication, location, study design, respiratory condition explored, study population (age, gender, ethnicity) and study findings (Table 2). A summary of the characteristics of the studies is also provided (Table 3).
| Author (year), location | Aim | Target condition | Study design & duration | Culturally responsive approach | Study population | Demographics n = study participants; Age, gender (%); ethnicity (%) | Main findings | |
|---|---|---|---|---|---|---|---|---|
| Bibby et al. (2015), 24 New Zealand | To investigate hospital admissions for non-cystic fibrosis bronchiectasis and to describe their distribution and annual cost in New Zealand. | Bronchiectasis | Retrospective cohort study | No cultural approach mentioned | Mixed | n = 5519 | Reported hospital admissions for bronchiectasis were concentrated in socioeconomically disadvantaged young and elderly Māori and Pacific peoples; are more common in winter and spring and incur a high annual cost. | |
| 4 years | Age: 0–>90 years | |||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (26%); Pacific (20%); European/Other (53%) | ||||||||
| Byrnes et al. (2020), 32 New Zealand | To reduce intermediate respiratory morbidity with a community intervention programme at the time of discharge. | Lower respiratory tract infection (LRTI) | Randomised control trial | No cultural approach mentioned | Mixed | n = 400 | Despite consistent monitoring at community clinics, treatment for respiratory symptoms, promotion of health-resilient behaviours, and referrals for environmental issues, there was no difference between intervention and control children in the high prevalence of respiratory morbidity 2 years after the initial admission. | |
| Age: <2 years | ||||||||
| Gender: Female (43%), Male (57%) | ||||||||
| Ethnicity: Māori (26%); Pacific (62%) NZ European (9%), Other (3%) | ||||||||
| Crengle et al. (2011), 25 New Zealand | To describe the pharmacological management of children’s asthma and to assess whether there were ethnic differences in pharmacological management. | Asthma | Cross sectional study | No cultural approach mentioned | Mixed | n = 583 | The proportion of children with asthma who were receiving beta agonists and inhaled corticosteroids (ICS) were higher than that previously reported in New Zealand and the reported use of anticholinergics was low. Other findings show there is still room for further improvements to be made, particularly with respect to the use of inhaled corticosteroids among children who experience significant morbidity, the use of nebulisers, and the use of spacer devices. | |
| 23 months | Age: 2–14 years | |||||||
| Gender: Female (45%), Male (55%) | ||||||||
| Ethnicity: Māori (38%); Pacific (30%) European/Other (32%) | ||||||||
| Doyle et al. (2018), 44 Porirua | To examine effectiveness of oral probiotic Streptococcus salivarius K12 in preventing group A streptococcus (GAS) pharyngitis in 5–14-year-old children at high risk of acute rheumatic fever (ARF). | Acute rheumatic fever (ARF) | Nonrandomised study | No cultural approach mentioned | Mixed | n = 1314 | Reported S. salivarius K12 had modest nonsignificant effects on culture-positive sore throats when given at school, during the school day. The trial also reported the routine use of the probiotic in the prevention of pharyngitis associated with GAS detection was not supported. | |
| 1 year | Age: <6 (25.9%), 7–9 (40.4%), >10 (33.7) | |||||||
| Gender: Males (49%) | ||||||||
| Ethnicity: Māori (33%); Pacific (55%); NZ European (6%); Asian (5%); Middle Eastern / Latin American / African (MELAA) (2%) | ||||||||
| Free et al. (2010), 33 Porirua, Hutt Valley, Christchurch, Dunedin/Bluff | To determine whether more effective home heating affects school absence for children with asthma. | Asthma | Randomised control trial | No cultural approach mentioned. | Mixed | n = 269 (Intervention Group 134/Control Group = 135) | Reported when compared with the control group, children in households receiving the intervention experienced on average 21% fewer days of absence after allowing for the effects of other factors. More effective, non-indoor polluting heating reduces school absence for asthmatic children. | |
| 1 year | Age: 6–12 years | |||||||
| Gender: Males (59%) | ||||||||
| Ethnicity: Māori (32%); PI (22%); NZ European (67%); Other (9.3%) | ||||||||
| Gill et al. (2012), 37 Dunedin | To Identify the prevalence of sleep disordered breathing (SDB) symptoms in a community sample of New Zealand 3-year-olds. To examine sleep, demographic, health, environmental, familial, perinatal, and behavioural adjustment factors associated with habitual snoring. | Sleep disordered breathing (SDB, snoring) | Cross sectional study | No cultural approach mentioned | Mixed | n = 823 | Reported the factors associated with habitual snoring among New Zealand pre-schoolers include male gender, Māori ethnicity and poorer deprivation neighbourhood, as well as a variety of other environmental and health factors. | |
| 1 year | ||||||||
| Age: 3 years | ||||||||
| Gender: Male (53%); Female (47%) | ||||||||
| Ethnicity: Māori (11%); Pacific (2%); NZ Euro (83%); Other (4%) | ||||||||
| Gillies et al. (2013), 50 New Zealand | To measure recommended treatment and outcomes for asthma in all New Zealand children by age, sex, and ethnic group. | Asthma | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 80,514 | Reported Mãori and Pacific children are less likely to have their treatment escalated to a higher step than other children. They are also more likely to use oral steroids to control asthma exacerbations and be admitted to hospital for severe asthma episodes. | |
| 1 year | ||||||||
| Age (range): 0–14 years | ||||||||
| Gender: Males (58%); Females (42%) | ||||||||
| Ethnicity: Māori (24%); Pacific (10%); European/Other (66%) | ||||||||
| Hobbs et al. (2017), 49 New Zealand | To identify risk factors for infectious disease hospitalisation in infancy within a birth cohort of New Zealand children, and to identify differences in risk factors between ethnic groups. | Infectious disease | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 5960 | Reported Māori and Pacific children in New Zealand experience a high burden of infectious disease hospitalisation. Reported risk factors include maternal smoking. | |
| 1 year | Age (range): 0–12 months | |||||||
| Gender: Male (52%) | ||||||||
| Ethnicity: Māori (13%), Pacific (14%), European (56%), Asian (2%), MELAA (2%) | ||||||||
| Huang et al. (2019), 46 New Zealand | To estimate attack rates (a measure of cumulative incidence of infection over the season) of both influenza infection symptomatic or not) and influenza polymerase chain reaction (PCR)–confirmed influenza-like illness (ILI) across risk groups in unvaccinated cohort and the proportion of those that sought medical care | Influenza | Seroepidemiologic cohort study | No cultural approach mentioned. | Mixed | n = 911 | Young children (<5 and 5–19 years) including Pacific peoples experienced the highest influenza infection attack rates. Overall, only a quarter of all infected reported influenza PCR-confirmed ILI, and one-quarter of these sought medical attention. | |
| 8 months | ||||||||
| Age (range): 0–4 (15%); 5–19 (29%); 20–64 (49%); >65 (5%) | ||||||||
| Gender: Males (41%); Females (49%) | ||||||||
| Ethnicity: Māori (14%); Pacific (11%); Asian (22%); Other (54%) | ||||||||
| Ingham et al. (2019), 45 Wellington | To examine the distribution of housing-related risk factors for children with severe acute respiratory infection to form an effective basis for policy and practice to reduce inequalities and prevalence of this disease. | Acute respiratory infection | Case–control study | Kaupapa Māori framework | Mixed | n = 642 | Reported a dose-response relationship between housing quality measures and young children's acute respiratory infection, particularly dampness and mould. | |
| 2 years | ||||||||
| Age: <2 years | ||||||||
| Gender: Males (53%) | ||||||||
| Ethnicity: Māori (28%); Pacific (20%); Asian (10%); NZ European (76%); Other (2%) | ||||||||
| Jack et al. (2018), 51 New Zealand | To evaluate the impact of the school-based sore throat service with its unique primary prevention focus on ARF | Acute rheumatic fever (ARF) | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 53,376 | Reported population-based primary prevention of acute rheumatic fever through sore throat management may be effective in well-resourced settings like New Zealand where high-risk populations are geographically concentrated. Where high-risk populations are dispersed, a school-based primary prevention approach appears ineffective and expensive. | |
| 4 years | ||||||||
| Age (range): 5–12 years | ||||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (47%); Pacific (41%); Pakeha (12%) | ||||||||
| Jepsen et al. (2018), 27 South Auckland | To explore the health care experiences of mothers of children with bronchiectasis in the Counties Manukau District Health Board area of Auckland, New Zealand. | Bronchiectasis | Qualitative | No cultural approach mentioned. | Mixed | n = 10 | Reported health provider–parent relationship was crucial for fostering positive health care experiences. Mothers perceptions of the quality and benefit of health services motivated them to overcome barriers to accessing care. | |
| 14 months | ||||||||
| Age (range): 3–16 years | ||||||||
| Gender: Females (100%) | ||||||||
| Ethnicity: Māori (30%); Pacific (50%); NZ Pakeha (20%); Other (10%) | ||||||||
| Jones et al. (2013), 41 Wellington | To collect and understand the insights of Māori parents, and their children, exploring their day-to-day realities, beliefs about asthma management as well as their experiences and challenges in achieving optimum asthma outcomes. | Asthma | Qualitative | Kaupapa Māori framework | Māori | n = 32 (families) | Reported the methodology produced a 100% retention rate of the participating families over the course of the follow-up. This was attributed to the research collaboration, the respectful research relationships established with families, and the families’ judgement that the methods used enabled them to tell their stories. | |
| Age (range): Child 4–11 years | ||||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori | ||||||||
| Kristiansen et al. (2012), 26 Auckland NZMJ | To evaluate a pictorial asthma medication plan focusing on regular ‘everyday’ inhaler use and a signs and symptoms sheet for Pacific children | Asthma | Prospective cohort study | Resources translated into Pacific languages. | Pacific | n = 48 | The resources were effective at improving inhaler knowledge and supporting symptom recognition. A ‘less-is-more’ approach, pictorial format, and first language availability are characteristics that may benefit other ethnicities. | |
| 11 months | Age: 2–14 years | |||||||
| Gender: Female (48%), Male (52%) | ||||||||
| Ethnicity: Samoan (65%); Cook Island Māori (8%); Niuean (8%); Tongan (6%); Fijian (4%); Tuvaluan (4%); Other Pacific (4%) | ||||||||
| Lennon et al. (2017), 28 South Auckland | To assess the effectiveness of a school based sore throat clinic strategy on first presentation acute rheumatic fever incidence | Acute rheumatic fever (ARF) & Group A streptococcal (GAS) | Cross sectional study | No cultural approach mentioned | Mixed | n = 1500 | Acute rheumatic fever declined significantly after school-based GAS pharyngitis management using oral amoxicillin paralleled by a decline in pharyngeal GAS prevalence | |
| 6 years | ||||||||
| Age: 5–13 years | ||||||||
| Gender: Female (50%) | ||||||||
| Ethnicity: Māori (40%); Pacific (45%); Other (15%) | ||||||||
| Liberty et al. (2010), 42 Christchurch | To evaluate whether entering school with asthma was associated with low achievement after the first year | Asthma | Prospective cohort study | No cultural approach mentioned | Mixed | n = 298 | Reported children who entered school with asthma were more likely to be ≥6 months behind other participants in reading words and books but not in math at the end of the first year of school. Achievement was not related to asthma severity. Entering school with asthma reliably predicted low reading achievement independent of other known covariates of low achievement (high absenteeism, minority status, male gender, single-parent family, poor academic skills at school entry, and low socioeconomic status). | |
| 1 year | ||||||||
| Age: 5–6 years | ||||||||
| Gender: Males (48.9%); Females (51.3%) | ||||||||
| Ethnicity: Māori (15.8%); European (74.8%); Other (9.4%) | ||||||||
| McBride-Henry et al. (2020), 29 South Auckland | To explore the experiences of parents/caregivers who encounter repeated admissions of a child with acute lower respiratory tract infections (LRTIs) | Lower respiratory tract infection (LRTI) | Qualitative | Cultural consultation undertaken with Māori Research Review Committee | Mixed | n = 14 | Reported parents/caregivers’ experiences were characterised by feelings of powerlessness, offering descriptions of hospitals as harsh and difficult places to reside and 'in-hospitable'. ’The findings suggest that repeated hospitalisations created a cycle of stressful experiences that impacted both familial relationships and interactions with society. | |
| Age (range): Child aged <14 years | ||||||||
| Gender: Male (21%); Female (86%) | ||||||||
| Ethnicity: Māori (43%); Pacific (71%); European (7%) | ||||||||
| McBride-Henry et al. (2022), 40 South Auckland | To explore the societal and health experiences for families who have a child under 2 years of age, admitted to hospitals more than twice for LRTIs | Lower respiratory tract infection (LRTI) | Qualitative | Cultural advisors utilised. | Mixed | n = 14 | Reported the importance of bringing meaningful, culturally responsive care to the fore of treatment, particularly when managing vulnerable minorities. Formal referral and support processes were key to this responsiveness to lessen the burdens of acute admissions for families. | |
| Age (range): Child aged <14 years | ||||||||
| Gender: Male (21%); Female (86%) | ||||||||
| Ethnicity: Māori (43%); Pacific (71%); European (7%) | ||||||||
| Moyes et al. (2012), 34 Auckland; Bay of Plenty; Wellington; Nelson; Christchurch | To investigate prevalence, time trends and factors associated with rhinitis and rhinoconjunctivitis not related to acute infections in New Zealand. | Upper respiratory tract infection (URTI, rhinitis and rhinoconjunctivitis) | Retrospective cohort study | No cultural approach mentioned. | Mixed | Phase 1&3 (6–7 years) n = 11,393/10,873 | Reported symptoms of rhinoconjunctivitis common in Māori and Pacific Island children, especially in the older age group 13–14-year-olds reported high prevalence of current severe rhinoconjunctivitis symptoms | |
| 1 year | Phase 1&3 (13–14 years) n = 15,460/13,317 | |||||||
| Age (range): 6–7 years & 13–14 years | ||||||||
| Gender: Females: 51%/50% (6–7 years); 46%/48% (13–14 years) | ||||||||
| Ethnicity: 6–7 years = Māori (20%/24%); Pacific (8%/8%); European/Pakeha (66%/56%); Other (5%/12%); 13–14 years = Māori (19%/19%); Pacific (8%/12%); European/Pakeha (64%/56%); Other (7%/12%) | ||||||||
| Munro et al. (2011), 39 Auckland | To document 5‐year outcomes of children with chest computerised tomography (CT) scan diagnosed bronchiectasis from a tertiary New Zealand respiratory clinic. | Bronchiectasis | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 91 | Reported reduced lung function was associated with male gender, chronic Haemophilus influenzae infection, longevity of disease, and Māori and Pacific Island ethnicity. | |
| 5 years | ||||||||
| Age: n/a | ||||||||
| Gender: Males (54%); Females (46%) | ||||||||
| Ethnicity: Māori (24%); Pacific (59%); European (15%); Other (2%) | ||||||||
| Oliver et al. (2017), 47 New Zealand | To investigate ARF cases’ housing conditions and sore throat treatment to identify opportunities for improving ARF prevention in New Zealand. | Acute rheumatic fever (ARF) | Cross sectional study | No cultural approach mentioned | Mixed | n = 55 | The environmental conditions reported could contribute to high group A Streptococcus transmission and susceptibility to infection, thus increasing ARF risk. Sore throat treatment has important limitations as an intervention, particularly as 38% of participants did not recall sore throat preceding the diagnosis. The results support the need to improve rental housing. | |
| 14 months | Age: 0–31 years | |||||||
| Gender: Female (53%), Male (47%) | ||||||||
| Ethnicity: Māori (64%); Pacific (35%) Other (2%) | ||||||||
| Oliver et al. (2018), 43 New Zealand | This study aimed to assess the effectiveness of using hospitalisations for identifying children at risk of subsequent acute rheumatic fever | Acute rheumatic fever (ARF) | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 2035 | Reported nearly one-third of acute rheumatic fever patients experienced a potentially avoidable hospital admission as children (before developing ARF). Due to the rarity of ARF however, observing hospitalisations was viewed as not efficient for targeting prevention activities for this condition alone. | |
| 4 years | ||||||||
| Age: <5 (0.5%), 5–14 (58.7%), 15–29 (25.6%), >29 (15.2%) | ||||||||
| Gender: Male (54%) | ||||||||
| Ethnicity: Māori (46%), Pacific (39%), European/Other (15%) | ||||||||
| Prasad et al. (2019), 48 Auckland | To provide comprehensive estimates of laboratory-confirmed respiratory syncytial virus (RSV)-associated hospitalisations. | Respiratory syncytial virus (RSV) | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 71,770 | Reported being of Māori or Pacific ethnicity or living in a low socio-economic neighbourhood independently increased the risk of having an RSV-associated hospitalisation. | |
| 3 years | Age: <5 years | |||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (14%); Pacific 27%); European & Other (35%) | ||||||||
| Shetty et al. (2014), 22 Northland | To assess adherence by general practitioners and school-based sore throat programmes to national guidelines for the management of GAS pharyngitis in Northland. | Group A streptococcal (GAS) | Audit | No cultural approach mentioned. | Māori & Non-Māori | n = 5411 | Reported a significant proportion of those seen in general practice received antibiotics no recommended by guidelines, an inadequate length of treatment or no prescription | |
| 3 months | ||||||||
| Age (range): 5–15 years | ||||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (62%); Non-Māori (38%) | ||||||||
| Shetty et al. (2018), 23 Northland | To reassess general practice adherence to national guidelines for the management of GAS pharyngitis in Northland, New Zealand, following implementation of the national Rheumatic Fever Prevention Programme. | Group A streptococcal (GAS) | Audit | No cultural approach mentioned. | Māori & Non-Māori | n = 5795 (swabs) | Reported the management of GAS pharyngitis by general practice in Northland remains substandard. | |
| 3 months | ||||||||
| Age (mean): Māori 9.1 years; Non-Māori (9.6 years) | ||||||||
| Gender: Males (46%) | ||||||||
| Ethnicity: Māori (52%); Non-Māori (48%) | ||||||||
| Trenholme et al. (2013), 31 South Auckland | To determine and describe the presence of respiratory morbidity in young children 1 year after being hospitalised with a severe LRTI. | Lower respiratory tract infection (LRTI) | Retrospective cohort study | No cultural approach mentioned. | Mixed | n = 94 | Most of the children hospitalised with severe bronchiolitis or pneumonia <2 years of age were found to have continued respiratory morbidity 1 year later when seen at the time of stability, with a small number already having sustained significant lung disease. | |
| 5 months | ||||||||
| Age (range): 0–24 months | ||||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (21%); Pacific (65%); Other (14%) | ||||||||
| Trenholme et al. (2017), 30 South Auckland | To describe respiratory virus detection in children under 2 years of age in a population admitted with LRTI and to assess correlation with measures of severity. | Lower respiratory tract infection (LRTI) | Retrospective cohort study | No cultural approach mentioned. | Māori & Pacific | n = 1371 | Reported picornavirus is commonly found as a sole virus, RSV is frequent, but immunisation preventable influenza is infrequent among Māori and Pacific children. | |
| 1 year | ||||||||
| Age: <2 years | ||||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (34%); Pacific (43%) | ||||||||
| Walsh et al. (2020), 36 Bay of Plenty | To evaluate the effectiveness of strategies for reducing ARF with GAS pharyngitis treatment in 2011–18. | Acute rheumatic fever (ARF) | Retrospective cohort study | No cultural approach mentioned | Māori | n = 128 | School-based programs with indigenous Māori health workers’ sore-throat swabbing and GP/nurse support reduced first-presentation ARF incidence in Māori students in highest-risk settings. | |
| Age: 5–14 years | ||||||||
| Gender: n/a | ||||||||
| Ethnicity: Māori (100%) | ||||||||
| Watson and McDonald (2013), 35 Upper North Island | To investigate the association of subcutaneous body fat levels in pregnant women with wheezing in their 18-month-old infants | Asthma & Wheeze | Prospective cohort study | No cultural approach mentioned. | Māori & Pacific | n = 369 | Reported a significant intergenerational association between subcutaneous body fat levels in pregnant women and wheeze in their infants at 18 months, which may be a contributing factor to the increased incidence of asthma in New Zealand children. | |
| 1 year | Age: n/a | |||||||
| Gender: Females (100%) | ||||||||
| Ethnicity: Polynesian (Māori & Pacific) |
| Number of studies | % of total studies n = 29 | ||
|---|---|---|---|
| Respiratory condition | |||
| Asthma | 7 | 24 | |
| GAS/ARF | 7 | 24 | |
| LRTI | 5 | 17 | |
| Bronchiectasis | 3 | 10 | |
| URTI | 2 | 7 | |
| Influenza | 1 | 3 | |
| RSV | 1 | 3 | |
| Infectious disease | 1 | 3 | |
| Respiratory tract infection | 1 | 3 | |
| Snoring | 1 | 3 | |
| Study location | |||
| Northland | 2 | 7 | |
| Whangarei | 1 | 3 | |
| Auckland | 11 | 38 | |
| Bay of Plenty | 2 | 7 | |
| Wellington | 7 | 24 | |
| Nelson | 1 | 3 | |
| Christchurch | 3 | 10 | |
| Dunedin | 2 | 7 | |
| National (region not specified) | 8 | 28 | |
| Study design | |||
| Retrospective cohort study | 11 | 38 | |
| Qualitative | 4 | 14 | |
| Cross sectional study | 4 | 14 | |
| Prospective cohort study | 3 | 10 | |
| Randomised control trial | 2 | 7 | |
| Audit | 2 | 7 | |
| Nonrandomised study | 1 | 3 | |
| Case control | 1 | 3 | |
| Sero-epidemiologic cohort study | 1 | 3 | |
| Cultural frameworks | |||
| Kaupapa Māori | 2 | 7 | |
| Cultural consultation | 1 | 3 | |
| Sample size | |||
| <100 | 8 | 28 | |
| 100–199 | 1 | 3 | |
| 200–499 | 3 | 10 | |
| 500–999 | 5 | 17 | |
| 1000–4999 | 4 | 14 | |
| 5000–9999 | 4 | 14 | |
| >10,000 | 4 | 14 | |
| Number of studies | % of total studies N = 28 | ||
|---|---|---|---|
| Study population | |||
| Māori | 28 | 97 | |
| Pacific | 24 | 83 | |
| New Zealand European | 18 | 62 | |
| Asian | 5 | 17 | |
| Middle Eastern Latin American African | 2 | 7 | |
| Other | 16 | 55 | |
| Sample size of Māori | |||
| <20% | 5 | 17 | |
| 20–39% | 12 | 41 | |
| 40–59% | 7 | 24 | |
| 60–79% | 2 | 7 | |
| 80–99% | 0 | – | |
| 100% | 2 | 7 | |
| Sample size of Pacific | |||
| <20% | 5 | 17 | |
| 20–39% | 7 | 24 | |
| 40–59% | 7 | 24 | |
| 60–79% | 4 | 14 | |
| 80–99% | 0 | – | |
| 100% | 1 | 3 | |
| Gender of participants | |||
| Female and male | 20 | 69 | |
| Female only | 2 | 7 | |
| Male only | 0 | – | |
| Not disclosed | 7 | 24 | |
Data synthesis
Four authors (A. M. I., D. T., J. N., D. G.) performed a narrative synthesis of the studies meeting the inclusion criteria. Due to the mix of study designs and research approaches, studies were grouped and summarised under six headings as follows: (1) study characteristics, (2) participants, (3) study design and elements, (4) methods for recruitment or engagement, (5) cultural frameworks used and (6) outcomes.
Results
Out of the initial 539 articles retrieved from electronic database searches (93 from Medline, 151 from EBSCOHost, 279 from Scopus and 16 from PubMed), 518 records were screened by title and abstract after removing duplicates. From this screening, 461 articles were excluded. The full text of the remaining 57 studies was reviewed, focusing on respiratory conditions in Māori and Pacific children (aged 0–14 years) in New Zealand. After further review, 12 studies were excluded as they did not provide a sub-group analysis of ethnicity regarding the Māori and Pacific children. Twenty-nine studies met the inclusion criteria and are included in this review (Fig. 1). Five of these studies were published in New Zealand journals, such as the New Zealand Journal of Primary Healthcare22,23 and the New Zealand Medical Journal,24–26 while the remaining 24 were published in international, peer-reviewed journals. Refer to Table 3 for a summary of the characteristics of the included studies.
Study characteristics
Eight studies were based in New Zealand with no specified region. Eleven studies were based in Auckland, with six located explicitly in South Auckland.27–32 Two studies were conducted across multiple regions of New Zealand; the first was co-located across Porirua, Hutt Valley, Christchurch and Dunedin,33 and the second across Auckland, Bay of Plenty, Wellington, Nelson and Christchurch.34 Other study locations included Northland,22,23 the upper North Island,35 the Bay of Plenty36 and Dunedin.37
Most studies reported on respiratory conditions such as asthma (n = 7), group A streptococcal (GAS) and acute rheumatic fever (ARF) (n = 7), lower respiratory tract infections (LRTI) (n = 5), bronchiectasis (n = 3) and upper respiratory tract infections (URTI) (n = 2). Other respiratory conditions included influenza, respiratory syncytial virus (RSV), respiratory tract infection and snoring.
Participants
Most studies included Māori and Pacific children or whānau as part of a multi-ethnic cohort at the Level one ethnicity category.38 Five studies reported multiple ethnicities at the Level two category.26,29,31,39,40 Out of the 29 studies, 28 involved Māori children/whānau, while 24 focused on Pacific children/families. Two studies explicitly focused on Māori,36,41 and only one study had a Pacific-only cohort,26 although one study used the term ‘Polynesian’ to describe their combination of Māori and Pacific participants.35 The remaining studies included a mix of ethnicities such as New Zealand European, Asian, Middle Eastern, Latin American, African (MELAA), and Other ethnicities. Participant numbers varied across studies, ranging from 14 to over 80,000. Most studies had less than 100 participants, with some including less than 39% of Māori or Pacific participants. However, there were also studies with over 40% representation from these groups. Most studies included both male and female participants, while a few focused specifically on females. Some studies did not provide detailed information on participant age or gender, and only a limited number of studies presented comprehensive demographic tables.
Study design and intervention elements
Eleven of the 29 studies were retrospective cohort studies – including two audits – which used datasets from the New Zealand Ministry of Health, the Pharmaceutical Claims Data Mart (PHARMS), New Zealand Health Information Service (NZHIS) or the National Minimum Dataset (Hospital Events) to explore hospitalisation rates, treatment outcomes and prevalence of a range of respiratory conditions.
While four studies were qualitative, two studies were randomised control trials. The first lasted 12 months, where the control group was waitlisted for the intervention.33 The second was a single-blind trial enrolling children aged less than 2 years hospitalised for lower respiratory tract infections to intervention or control.32 Three were prospective cohort studies. In the first, the association between a pregnant mother’s maternal body fat and the prevalence of infant wheeze was explored,35 the second looked at whether starting school with known asthma contributed to low achievement after the first year of school42 and the third reviewed how translated Pacific resources assisted families with managing asthma with their children.26 Four were cross-sectional studies, where one assessed the prevalence of habitual snoring among New Zealand pre-schoolers,37 one explored the pharyngeal GAS prevalence among a cohort of children who attended schools with sore throat clinics,28 one investigated ARF cases’ housing conditions and sore throat treatment to identify opportunities to improve ARF prevention,43 while another described the pharmacological management of children’s asthma to assess whether there were ethnic differences in pharmacological management.25
Three of the four qualitative studies reported on the experiences of families whose children had respiratory infections.27,29,40 The fourth qualitative study41 captured the whānau and children’s perspectives of asthma and asthma management and used drawing lung representations as an interactive and fun way to engage with children. Other studies included a non-randomised study where children either received an intervention or placebo,44 a case control study that examined the distribution of housing-related risk factors for children with severe acute respiratory infection45 and a sero-epidemiologic cohort study which captured influenza infection rates by risk group.46 Time frames for each study ranged from 3 months to 6 years.
Methods for recruitment or engagement
Three studies recruited from a tertiary paediatric hospital, two focusing on children30,32 and the other on parents’ perspectives regarding their child’s respiratory health.29 Another study utilised a public health unit to reach out to families with children who had ARF,47 while a different study employed a research nurse and a community health worker to connect with families after their hospital admission.31 A similar approach was taken in another study,27 which recruited participants from a tertiary hospital and a paediatric and youth outpatient clinic, relying on clinical staff and flyers placed in waiting rooms. Recruitment challenges prompted this study to expand the age range (from 0–10 to 0–17 years) and adopt snowball sampling as an additional method.
Four studies26,35,41,45 worked alongside primary care and community organisations to recruit, with one study also advertising in the local newspaper and on the radio.33 One of these studies, conducted by Jones et al.,41 worked closely with nurses at a community-based organisation – Tu Kotahi Māori Asthma Trust – known for its work with Māori communities. This partnership used kanohi-ki-te-kanohi (face to face approach), facilitated by the organisation’s nurses, leading to the involvement of other families through snowball sampling. A Māori researcher subsequently met with participants to explain the study and obtain written consent. Ingham’s study,45 a sub-study within the Whiti Te Ra Case Control Study, provided a flow diagram outlining the recruitment process. Although it did not provide detailed information on household recruitment, the study involved an advisory group comprising Māori and Pacific community members and local health care organisations, who played a role in recruitment procedures, study design and implementation.
Three studies collaborated with primary and intermediate schools to recruit children.28,42,44 Two studies directly contacted families through invitation letters and follow-up phone calls.37,46 Another study, consisting of three cohorts, worked alongside schools, a Māori health provider and a primary care organisation.36 In one study, random residential addresses were used as starting points, with households then being asked about the eligibility of their children, and caregivers were subsequently invited to participate.25 All studies involving direct contact with participants obtained ethics approval. Twelve studies did not require direct recruitment as they utilised previously reported datasets to collect the necessary information. However, two22,23 of these 12 studies sought approval from their District Health Board assessment committee and Primary Health Organisation clinical governance group before conducting their audits.
Culturally responsive approaches
Out of the 29 studies, only two studies reported utilising a Kaupapa Māori Research framework. The first study emphasised Māori leadership and tikanga (Māori cultural protocols) by involving Māori at all stages of the research, including the formation of an advisory group comprising Māori and Pacific community members and health care organisations.45 This partnership supported the development, design, recruitment and implementation phases of the study. In the second study, a qualitative approach was taken, involving interviews with whānau to understand their experiences related to asthma outcomes. Within this study, Kaupapa Māori methods were employed to recruit 32 Māori whānau, achieving a 100% retention rate. The researchers obtained formal ethics approval and sought consultation and permission from kaumātua and kuia (tribal elders) to undertake the research in partnership with their community, accompanied by a launch ceremony and blessing at their local marae.
One study29 reported conducting a cultural consultation to ensure Māori and Pacific perspectives were considered before submitting their ethics application. The study team also included Māori and Samoan researchers who assisted in reviewing research protocols, data analysis and findings. Another study adopted a bilingual approach in their intervention and provided translated asthma resources to families.26 While one study offered the availability of a translator if needed, it was not utilised.27 Several studies incorporated Māori and Pacific researchers or health care professionals in their team, although they were not the primary investigators.
Outcomes
Several studies addressed health disparities experienced by Māori and Pacific children, highlighting areas that require improvement. Two studies22,23 focused on the inadequate management of sore throats in primary care practices for Māori children, emphasising the need for significant improvements in this setting. Another study examined the ongoing respiratory morbidity 1 year after hospitalisation with pneumonia or severe bronchiolitis among Māori and Pacific children.31 Three studies reported disparities in hospitalisation rates for RSV,48 non-cystic fibrosis bronchiectasis24 and infectious diseases during the first year of life, comparing Māori and Pacific children with non-Māori/non-Pacific children.49
Regarding asthma management, one study25 found no ethnic differences in the use of spacers but revealed that Māori and Pacific children were more likely to receive a nebuliser than European/other children. The same study reported that Māori and Pacific children who experienced severe morbidity were less likely to receive inhaled corticosteroids. In another study,50 it was observed that Māori and Pacific children were less likely to have their asthma treatment escalated to a higher step (step one to step three) and were more likely to use oral steroids for asthma exacerbations and not receive prescribed asthma medication in primary care when admitted to the hospital. Other findings included the association between asthma and low reading achievement,42 higher prevalence of rhinoconjunctivitis symptoms among Māori and Pacific children,34 higher incidence of habitual snoring among Māori children37 and an association between subcutaneous body fat levels in pregnant women and wheezing in their infants at 18 months.35 The qualitative studies provided a range of participants’ experiences, with one study reporting a 100% retention rate,41 and another study26 highlighting the positive impact of translated resources on inhaler knowledge and symptom recognition for Pacific families.
The effectiveness of school-based sore throat clinics in reducing ARF hospitalisation rates was demonstrated in three studies.28,36,51 Two studies focused on housing conditions and found that improvements in housing quality measures such as dampness and mould led to a reduction in hospitalisations for acute respiratory infections,45 while another study showed improved school attendance among children with asthma who received a household intervention.33 Additionally, one study47 highlighted the role of environmental conditions in increasing the risk of ARF among families due to high GAS transmission and susceptibility to infection. One study44 reported no significant difference in the intervention group receiving treatment for GAS, while another43 reported observing hospitalisations for ARF were not efficient for targeting prevention activities for this condition.
Discussion
This systematic review, to our knowledge, is the first to explore and outline the characteristics of respiratory research specifically focused on Māori and Pacific children (aged 0–14 years) in New Zealand. In total, 29 studies were included in the review, offering valuable and novel insights. Most of these studies concentrated on asthma, GAS/ARF and LRTI, and were primarily conducted in Auckland, particularly South Auckland, as well as the Wellington region.
The included studies exhibited a diverse range of study designs, intervention components, recruitment strategies and methods of data collection and analysis. Retrospective cohort studies based on national datasets were the most common study design, followed by cross-sectional studies and qualitative studies that explored the experiences of whānau in managing their child’s asthma27,41 or caring for children hospitalised with respiratory conditions.29 Among the included studies, 28 focused on Māori children and/or their caregivers, while 24 involved Pacific populations, often with mixed variations of population groups and varying sample sizes. It is worth noting that the sample sizes varied, and only a few studies included more than 40% Māori and Pacific participants. Additionally, one study35 grouped Māori and Pacific participants together as ‘Polynesians,’ which can be problematic as it homogenises these distinct communities. Although Māori and Pacific communities share historical and cultural connections across Te-Moana-Nui-a-Kiwa,52 acknowledging their unique differences is essential and should not be overlooked.
Māori, as the indigenous people of Aotearoa New Zealand, have a special relationship with the Crown established through Te Tiriti o Waitangi. The Crown has a responsibility to protect and uphold the well-being of Māori based on the principles of Te Tiriti.52 Pacific people support the importance of Te Tiriti O Waitangi and are tauiwi within the bicultural framework that it establishes.52 ‘Pacific people’ is a collective term used to represent diverse communities from various countries in Polynesia, Melanesia and Micronesia, residing in New Zealand.53 It is important to note the differences among these Pacific countries in terms of language, customs, geography, migration history, constitutional ties and political influences.54,55 With each new generation born in New Zealand, the acquisition of additional ethnicities becomes relevant, as young people are increasingly identifying with multiple ethnic backgrounds.56 Only four studies in this review reported multiple ethnicities at level two, acknowledging the ethnic mobility of a new generation of children.26,29,31,39 Using the standard prioritisation of Māori ethnicity however unintentionally creates under-reporting of Pacific people who are more likely to report multiple ethnicities. A researcher’s judgement on ethnic affiliation and classification of participants therefore needs to be guided by appropriate Māori and Pacific leadership to ensure data consistency and accurate reporting.57
Several studies have drawn attention to the persistent health disparities experienced by Māori and Pacific children, particularly in relation to inadequate management of sore throats in primary care,22,23 insufficient asthma treatment and care in hospitals50 or primary care,25 and the ongoing respiratory health issues even after hospitalisation for severe bronchiolitis or pneumonia.31,32 It is not surprising that Māori and Pacific communities have historically faced discrimination, unconscious biases and racism within the health care system.5,58 The Waitangi Tribunal report acknowledges that the Crown have failed to address Māori health inequities and were in breach of Te Tiriti O Waitangi.59 To truly advance Māori health, which ultimately benefits all New Zealanders, there is a need for investment in culturally appropriate and impactful research and health care approaches.19
Three studies28,36,44 found that schools were effective in treating sore throats and extending treatment to family members. This highlights the acceptability and accessibility of schools treating preventable respiratory conditions in children. Despite free primary care for children, barriers to access remain, including financial constraints, transportation issues, distance, childcare and work commitments.5,6 Three studies highlighted the importance of addressing housing conditions and household income in improving respiratory outcomes.33,45,47 Māori and Pacific populations, who often live in overcrowded housing with poor ventilation, are particularly affected.33,45,47,60 The typical design of New Zealand homes often fails to accommodate the lifestyles of most Māori and Pacific families.61 Efforts to improve housing design and availability are crucial to prevent respiratory diseases associated with housing conditions.47,62
Acknowledging and utilising culturally responsive and indigenous approaches is critical when conducting research with Māori and Pacific communities. Only two studies explicitly employed a Kaupapa Māori Framework,29,41 with others incorporating the use of tikanga, translators, Māori and Pacific researchers and undertaking a cultural consultation. It is recommended that such approaches be considered for a broader range of studies involving Māori and Pacific communities. Building partnerships with Māori communities and health providers, as exemplified by Jones et al.s’ study,41 is important for research to yield tangible benefits. Tuhiwai Smith18 describes how researchers should, whenever conducting research regarding Indigenous peoples, centre Indigenous values and follow Indigenous protocols. The acknowledgement of Maori and Pacific research approaches as valid methodologies and methods recognises the move away from Eurocentric frameworks.63 It also recognises cultural frameworks can be applied to support research processes. Furthermore, co-designing interventions that incorporate Māori and Pacific frameworks is essential. In a review of Kaupapa Māori health interventions undertaken by Rolleston and colleagues,64 the Ol@-Or@ mHealth Tool study65 highlighted the integration of cultural values and co-design throughout the research process, enabling Māori and Pacific values and aspirations about wellbeing to be captured and implemented into the design and application of the intervention. More studies focusing on the needs of Māori and Pacific families and communities are needed to ensure culturally responsive care and tailored approaches.24,27 Authentic partnerships and co-design from the outset are essential to acknowledge and translate health aspirations and interactions within the health care system.64
A strength of this systematic review lies in its comprehensive approach, synthesising existing research on respiratory health in Māori and Pacific children (10–14) in New Zealand. However, limitations include the heterogeneous range of studies found, preventing meta-analysis to assess the quality of the research or interventions within the studies. Additionally, the focus is limited to a period of 12 years (2010–2022) and primarily Māori and Pacific children, potentially excluding other relevant respiratory studies in New Zealand.
Conclusion
This review underscores the remaining challenges in improving respiratory health outcomes for Māori and Pacific children, emphasising the need for culturally appropriate frameworks and approaches guided by Te Tiriti O Waitangi and Pacific values in research practices. To achieve equity, Māori and Pacific communities should be considered equal research partners, actively involved in all stages of the research process, going beyond mere consultation. Additionally, the scarcity of qualitative studies exploring the experiences of Māori and Pacific families within the health care system highlights the importance of including their voices in shaping health aspirations for whānau and families. These insights are crucial for future service planning, policy development and the responsiveness of health services to respiratory diseases.
Data availability
The data that supports this study will be shared upon reasonable request to the corresponding author.
Conflicts of interest
The author(s) declared no potential conflicts of interest with respect to the research, authorship and/or publication of this article.
Declaration of funding
This study was funded by a Cure Kids grant. The funders had no role in the design and conduct of the study; data collection, management, analysis, and interpretation; manuscript preparation or review; or the decision to submit the manuscript for publication.
References
1 Child Poverty Action Group. Left further behind: How New Zealand is failing its children. Auckland: Child Poverty Action Group; 2011. Available at https://www.cpag.org.nz/assets/sm/upload/d4/ei/sg/g4/LFBDec2011.pdf
2 Cure Kids. State of child health in Aotearoa New Zealand. Auckland: Cure Kids; Available at https://www.curekids.org.nz/downloads/assets/5c03/1
3 Duncanson M, Oben G, Adams J, et al. Health and wellbeing of under-15 year olds in the Northland region 2018 (Health and wellbeing of under-15 year olds). 2019. Available at http://hdl.handle.net/10523/9438
4 Ministry of Health. Pacific child health. A paper for the Pacific health and disability action plan review. Wellington: Ministry of Health; 2008. Available at https://www.health.govt.nz/publication/pacific‐peoples‐and‐mental‐health‐paper‐pacific‐health‐and‐disability‐action‐plan‐review
5 Ryan D, Grey C, Mischewski B. Tofa Saili: A review of evidence about health equity for Pacific Peoples in New Zealand. Wellington: Pacific Perspectives Ltd; 2019. Available at https://www.pacificperspectives.co.nz/_files/ugd/840a69_e60e351af88048ed8fa005ad28955f9a.pdf
6 Palmer SC, Gray H, Huria T, et al. Reported Māori consumer experiences of health systems and programs in qualitative research: a systematic review with meta-synthesis. Int J Equity Health 2019; 18: 163.
| Crossref | Google Scholar | PubMed |
7 Schlichting D, Fadason T, Grant CC, et al. Childhood asthma in New Zealand: the impact of ongoing socioeconomic disadvantage (2010–2019). N Z Med J 2021; 134(1533): 80-95.
| Google Scholar | PubMed |
8 Simpson J, Duncanson M, Oben G, et al. The health status of Pacific children and young people in New Zealand 2015. Dunedin: New Zealand Child and Youth Epidemiology Service; 2017. Available at http://hdl.handle.net/10523/7391
9 Simpson J, Oben G, Craig E, et al. The determinants of health for children and young people in New Zealand (2014). Dunedin: New Zealand Child and Youth Epidemiology Service; 2016. Available at http://hdl.handle.net/10523/6383
12 Ministry of Health. He Korowai Oranga: Māori health strategy. Wellington: Ministry of Health; 2014. Available at http://www.health.govt.nz/our-work/populations/Māori-health/hekorowai-oranga
13 Ministry of Health. Equity of health care for Māori: A framework. Wellington: Ministry of Health; 2014. Available at http://www. health.govt.nz/publication/equity-health-care-Māoriframework
15 Ministry for Pacific Peoples. All-of-Government Pacific Wellbeing Strategy. Wellington, New Zealand: Ministry for Pacific Peoples; 2022. Available at https://www.mpp.govt.nz/assets/Reports/Pacific-Aotearoa-Lalanga-Fou-Report.pdf
16 Ofanoa M, Percival T, Huggard P, et al. Talanga: the Tongan way enquiry. Sociol Study 2015; 5(4): 334-340.
| Crossref | Google Scholar |
19 Health Research Council. Māori health advancement guidelines. Auckland: Health Research Council of New Zealand; 2019. Available at https://gateway.hrc.govt.nz/funding/downloads/HRC_Maori_Health_Advancement_Guidelines.pdf
20 Moher D, Liberati A, Tetzlaff J, et al. Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. PLoS Med 2009; 6(7): e1000097.
| Crossref | Google Scholar | PubMed |
21 Aromataris E, Fernandez R, Godfrey CM, et al. Summarizing systematic reviews: methodological development, conduct and reporting of an umbrella review approach. Int J Evid Based Healthc 2015; 13(3): 132-140.
| Crossref | Google Scholar | PubMed |
22 Shetty A, Mills C, Eggleton K. Primary care management of group A streptococcal pharyngitis in Northland. J Prim Health Care 2014; 6(3): 189-194.
| Google Scholar | PubMed |
23 Shetty A, Mills C, Eggleton K. A repeat audit of primary care management of group A streptococcal pharyngitis in Northland, New Zealand 2016. J Prim Health Care 2018; 10(1): 18-24.
| Crossref | Google Scholar | PubMed |
24 Bibby S, Milne R, Beasley R. Hospital admissions for non-cystic fibrosis bronchiectasis in New Zealand. N Z Med J 2015; 128(1421): 30-38.
| Google Scholar | PubMed |
25 Crengle S, Robinson E, Grant C, et al. Pharmacological management of children’s asthma in general practice: findings from a community-based cross-sectional survey in Auckland, New Zealand. N Z Med J 2011; 124(1346): 44-56.
| Google Scholar | PubMed |
26 Kristiansen J, Hetutu E, Manukia M, et al. An evaluation of a pictorial asthma medication plan for Pacific children. N Z Med J 2012; 125(1354): 42-50.
| Google Scholar | PubMed |
27 Jepsen N, Charania NA, Mooney S. Health care experiences of mothers of children with bronchiectasis in Counties Manukau, Auckland, New Zealand. BMC Health Serv Res 2018; 18: 722 722.
| Crossref | Google Scholar |
28 Lennon D, Anderson P, Kerdemilidis M, et al. First presentation acute rheumatic fever is preventable in a community setting: a school-based intervention. Pediatr Infect Dis J 2017; 36(12): 1113-1118.
| Crossref | Google Scholar | PubMed |
29 McBride-Henry K, Miller C, Trenholm A, et al. Occupying ‘in-hospitable’ spaces: parental/primary-caregiver perceptions of the impact of repeated hospitalisation in children under two years of age. PLoS ONE 2020; 15(1): e0228354.
| Crossref | Google Scholar | PubMed |
30 Trenholme AA, Best EJ, Vogel AM, et al. Respiratory virus detection during hospitalisation for lower respiratory tract infection in children under 2 years in South Auckland, New Zealand. J Paediatr Child Health 2017; 53(6): 551-555.
| Crossref | Google Scholar | PubMed |
31 Trenholme AA, Byrnes CA, McBride C, et al. Respiratory health outcomes 1 year after admission with severe lower respiratory tract infection. Pediatr Pulmonol 2013; 48: 772-779.
| Crossref | Google Scholar | PubMed |
32 Byrnes CA, Trenholme A, Lawrence S, et al. Prospective community programme versus parent-driven care to prevent respiratory morbidity in children following hospitalisation with severe bronchiolitis or pneumonia. Thorax 2020; 75(4): 298-305.
| Crossref | Google Scholar | PubMed |
33 Free S, Howden-Chapman P, Pierse N, et al. More effective home heating reduces school absences for children with asthma. J Epidemiol Community Health 2010; 64(5): 379-386.
| Crossref | Google Scholar | PubMed |
34 Moyes CD, Clayton T, Pearce N, et al. Time trends and risk factors for rhinoconjunctivitis in New Zealand children: an International Study of Asthma and Allergies in Childhood (ISAAC) survey. J Paediatr Child Health 2012; 48(10): 913-920.
| Crossref | Google Scholar | PubMed |
35 Watson PE, McDonald BW. Subcutaneous body fat in pregnant New Zealand women: Association with wheeze in their infants at 18 months. Matern Child Health J 2013; 17(5): 959-967.
| Crossref | Google Scholar | PubMed |
36 Walsh L, Innes-Smith S, Wright J, et al. School-based streptococcal A sore-throat treatment programs and acute rheumatic fever amongst Indigenous Māori: a retrospective cohort study. Pediatr Infect Dis J 2020; 39(11): 995-1001.
| Crossref | Google Scholar | PubMed |
37 Gill AI, Schaughency E, Galland BC. Prevalence and factors associated with snoring in 3-year olds: early links with behavioral adjustment. Sleep Med 2012; 13(9): 1191-1197.
| Crossref | Google Scholar | PubMed |
38 Ministry of Health. HISO 10001:2017 ethnicity data protocols. Wellington: Ministry of Health; 2017. Available at https://www.health.govt.nz/system/files/documents/publications/hiso_10001-2017_ethnicity_data_protocols_may-21.pdf
39 Munro KA, Reed PW, Joyce H, et al. Do New Zealand children with non-cystic fibrosis bronchiectasis show disease progression? Pediatr Pulmonol 2011; 46(2): 131-138.
| Crossref | Google Scholar | PubMed |
40 Mcbride-Henry K, Miller C, Trenholm A, et al. ‘You have to do what is best’: the lived reality of having a child who is repeatedly hospitalized because of acute lower respiratory infection. Health Expect 2022; 25(1): 466-475.
| Crossref | Google Scholar | PubMed |
41 Jones B, Ingham TR, Cram F, et al. An indigenous approach to explore health-related experiences among Māori parents: the Pukapuka Hauora asthma study. BMC Public Health 2013; 13(1): 228.
| Crossref | Google Scholar | PubMed |
42 Liberty KA, Pattemore P, Reid J, et al. Beginning school with asthma independently predicts low achievement in a prospective cohort of children. Chest 2010; 138(6): 1349-1355.
| Crossref | Google Scholar | PubMed |
43 Oliver J, Foster T, Williamson DA, et al. Using preceding hospital admissions to identify children at risk of developing acute rheumatic fever. J Paediatr Child Health 2018; 54(5): 499-505.
| Crossref | Google Scholar | PubMed |
44 Doyle H, Pierse N, Tiatia R, et al. Effect of oral probiotic streptococcus salivarius K12 on group A streptococcus pharyngitis: a pragmatic trial in schools. Pediatr Infect Dis J 2018; 37(7): 619-623.
| Crossref | Google Scholar | PubMed |
45 Ingham T, Keall M, Jones B, et al. Damp mouldy housing and early childhood hospital admissions for acute respiratory infection: a case control study. Thorax 2019; 74(9): 849-857.
| Crossref | Google Scholar | PubMed |
46 Huang QS, Bandaranayake D, Wood T, et al. Risk factors and attack rates of seasonal influenza infection: Results of the southern hemisphere influenza and vaccine effectiveness research and surveillance (SHIVERS) sero-epidemiologic cohort study. J Infect Dis 2019; 219(3): 347-357.
| Crossref | Google Scholar | PubMed |
47 Oliver JR, Pierse N, Stefanogiannis N, et al. Acute rheumatic fever and exposure to poor housing conditions in New Zealand: a descriptive study. J Paediatr Child Health 2017; 53(4): 358-364.
| Crossref | Google Scholar | PubMed |
48 Prasad N, Newbern EC, Trenholme AA, et al. Respiratory syncytial virus hospitalisations among young children: a data linkage study. Epidemiol Infect 2019; 147: e246.
| Crossref | Google Scholar | PubMed |
49 Hobbs MR, Morton SMB, Atatoa-Carr P, et al. Ethnic disparities in infectious disease hospitalisations in the first year of life in New Zealand. J Paediatr Child Health 2017; 53(3): 223-231.
| Crossref | Google Scholar | PubMed |
50 Gillies TD, Tomlin AM, Dovey SM, et al. Ethnic disparities in asthma treatment and outcomes in children aged under 15 years in New Zealand: analysis of national databases. Prim Care Respir J 2013; 22(3): 312-318.
| Crossref | Google Scholar | PubMed |
51 Jack SJ, Williamson DA, Galloway Y, et al. Primary prevention of rheumatic fever in the 21st century: evaluation of a national programme. Int J Epidemiol 2018; 47(5): 1585-1593.
| Crossref | Google Scholar | PubMed |
52 Health Research Council. Pacific health research guidelines. Auckland: Health Research Council New Zealand; 2014. Available at https://www.hrc.govt.nz/sites/default/files/2019-05/Resource%20Library%20PDF%20-%20Pacific%20Health%20Research%20Guidelines%202014_0.pdf
53 Ministry for Pacific Peoples. Pacific Aotearoa lalanga fou. Wellington: Ministry for Pacific Peoples; 2018. Available at https://www.mpp.govt.nz/assets/Reports/Pacific-Aotearoa-Lalanga-Fou-Report.pdf
54 Ministry for Pacific Peoples. Yavu: Foundations of Pacific engagement. Wellington: Ministry for Pacific Peoples; 2018. Available at https://www.mpp.govt.nz/assets/Uploads/MPP8836-Yavu-Pacific-Engagement-Digital-Book.pdf
55 Tiatia-Seath J. The importance of Pacific cultural competency in healthcare. Pac Health Dialog 2018; 21(1): 8-9.
| Crossref | Google Scholar |
56 Callister P, Didham R, Kivi A. Who are we? The conceptualisation and expression of ethnicity, Official Statistics Research Series 4. Wellington; 2009. Available at http://www.statisphere.govt.nz/official-statisticsresearch/series/default.htm
57 Stats NZ. Understanding and working with ethnicity data: A technical paper. Wellington: Statistics New Zealand; 2005. 10.13140/RG.2.1.1347.0804
58 Talamaivao N, Harris R, Cormack D, et al. Racism and health in Aotearoa New Zealand: a systematic review of quantitative studies. N Z Med J 2020; 133(1521): 55-68.
| Google Scholar | PubMed |
59 Waitangi Tribunal. Hauora: Report on stage one of the health services and outcomes kaupapa inquiry. Lower Hutt, New Zealand: Legislation Direct; 2019. Available at https://forms.justice.govt.nz/search/Documents/WT/wt_DOC_195476216/Hauora%202023%20W.pdf
60 Stats NZ. Living in a crowded house: Exploring the ethnicity and well-being of people in crowded households; 2018. Available at https://www.stats.govt.nz/reports/living-in-a-crowded-house-exploring-the-ethnicity-and-well-being-of-people-in-crowded-households [accessed 12 December 2021].
62 Jaine R, Baker M, Venugopal K. Acute rheumatic fever associated with household crowding in a developed country. Paediatr Infect Dis J 2011; 30(4): 315-319.
| Crossref | Google Scholar | PubMed |
63 Ponton V. Utilizing Pacific methodologies as inclusive practice. SAGE Open 2018; 8(3): 215824401879296.
| Crossref | Google Scholar |
64 Rolleston AK, Cassim S, Kidd J, et al. Seeing the unseen: evidence of kaupapa Māori health interventions. AlterNative 2020; 16(2): 129-136.
| Crossref | Google Scholar |
65 Ni Mhurchu C, Te Morenga L, Tupai-Firestone R, et al. A co-designed mHealth programme to support healthy lifestyles in Māori and Pasifika peoples in New Zealand (OL@-OR@): a cluster-randomised controlled trial. Lancet Digit Health 2019; 1(6): e298-e307.
| Crossref | Google Scholar | PubMed |
