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    SAMJ: South African Medical Journal

    On-line version ISSN 2078-5135Print version ISSN 0256-9574

    SAMJ, S. Afr. med. j. vol.108 n.5 Pretoria May. 2018

    https://doi.org/10.7196/samj.2018.v108i5.12862 

    RESEARCH

     

    Healthcare-associated infections in paediatric and neonatal wards: A point prevalence survey at four South African hospitals

     

     

    C OlivierI; H KunnekeII; N O'ConnellIII; E von DelftIV; M WatesV; A DramowskiVI

    I6th-year medical student; Faculty of Medicine and Health Sciences, Stellenbosch University, Cape Town, South Africa
    IIMB ChB, FC Paed (SA), MMed (Paed); Department of Paediatrics, Worcester Provincial Hospital, South Africa
    IIIMB ChB, MMed (Paed); Department of Paediatrics, Khayelitsha District Hospital, Cape Town, South Africa
    IVMB ChB, FCPaed, MMed (Paed); Department of Paediatrics, Paarl Hospital, South Africa
    VMB ChB, BSc, MMed (Paed); Department of Paediatrics, Karl Bremer Hospital, Cape Town, South Africa
    VIMB ChB, FC Paed (SA), MMed (Paed), Cert Paed ID, DCH, PhD; Division of Paediatric Infectious Diseases, Department of Paediatrics and Child Health, Faculty of Medicine and Health Sciences, Stellenbosch University, Cape Town, South Africa

    Correspondence

     

     


    ABSTRACT

    BACKGROUND. Healthcare-associated infections (HAIs) cause substantial morbidity, mortality and healthcare costs. The prevalence of neonatal/paediatric HAI at South African (SA) district and regional hospitals is unknown.
    OBJECTIVES. To document HAI rates, antimicrobial use for HAI, infection prevention staffing, hand hygiene (HH) provisions and HH compliance rates in neonatal and paediatric wards in two district and two regional hospitals in the Western Cape Province, SA.
    METHODS. An HAI point prevalence survey (PPS) was conducted in neonatal and paediatric wards at two district and two regional hospitals in the Western Cape during December 2016, applying National Healthcare Safety Network HAI definitions. HAI events and antimicrobial therapy active at 08h00 on the PPS day and during the preceding 7 days (period prevalence) were documented. Provisions for HH and HH compliance rates were observed on each ward using the World Health Organization's HH surveillance tool.
    RESULTS. Pooled point and period HAI prevalence were 9.9% (15/151; 95% confidence interval (CI) 6 - 15.8) and 12.6% (19/151; 95% CI 8 -18.9), respectively. Hospital-acquired pneumonia (5/15, 33.3%), bloodstream infection (3/15, 20.0%) and urinary tract infection (3/15, 20.0%) were predominant HAI types. Risk factors for HAI were a history of recent hospitalisation (8/19, 42.1% v. 17/132, 12.9%; p<0.001) and underlying comorbidity (17/19, 89.5% v. 72/132, 54.5%; p<0.004). HH provisions (handwash basins/alcohol hand rub) were available and functional. HH compliance was higher in neonatal than in paediatric wards (125/243, 51.4% v. 25/250, 10.0%; p<0.001). Overall HH compliance rates were higher among mothers (46/107, 43.0%) than nurses (73/265, 27.8%) and doctors (29/106, 27.4%).
    CONCLUSIONS. Neonatal and paediatric HAIs are common adverse events at district and regional hospitals. This at-risk population should be prioritised for HAI surveillance and prevention through improved infection prevention practices and HH compliance.


     

     

    Healthcare-associated infections (HAIs) are the most frequent complication of hospitalisation, resulting in increased morbidity, in-hospital mortality and healthcare costs.[1] Hospitalised neonates and children are at high risk for HAI owing to immunological immaturity, frequent handling by caregivers and increased in-hospital exposure to infectious diseases (notably viral respiratory and gastrointestinal pathogens).[1] HAI surveillance is an important tool in quantifying the burden of disease, planning infection prevention interventions and monitoring the impact of these strategies. However, HAI surveillance is seldom conducted in neonates and children in African hospitals, especially in district and regional hospital settings.[2-Furthermore, hospital design, provisions and human resources to implement best practices in infection prevention are limited in South African (SA) public healthcare facilities.[3]

    From the scant SA literature documenting HAI in hospitalised neonates and children, bloodstream infections (BSIs), urinary tract infections (UTIs) and hospital-acquired pneumonia (HAP) are the most prevalent HAI types.[3-5] In keeping with international literature, important risk factors for HAI in this population include prematurity, intensive care unit admission, malnutrition and the presence of indwelling devices.[3-7] HIV infection and HIV exposure have recently been identified as novel risk factors for HAI in SA children.[4,8]

    Limited data on neonatal HAI have been reported from three tertiary neonatal centres in SA, with healthcare-associated (HA) BSI rates of 3.9 (Tygerberg Hospital, Cape Town)[9] and 14/1 000 patient days (Charlotte Maxeke Johannesburg Academic Hospital, Johannesburg),[10] and an overall HAI incidence of 21.6/100 admissions at Grey's Hospital, Pietermaritzburg.[11] The prevalence of HAI among hospitalised children in Cape Town was 24%,[4 in stark contrast to the 5% rate determined in a recent Europe-wide paediatric HAI point prevalence survey (PPS).[6] Previous prospective HAI surveillance in 1989[5] and an HAI PPS in 2006,[3] conducted in paediatric wards at two Gauteng hospitals, established HAI prevalence rates of 14.3% and 16%, respectively, with a predominance of gastrointestinal infections, HA pneumonia and HA BSI. Paediatric HAI surveillance in other low- to middle-income countries (LMICs) reported considerable incidence and prevalence density rates of 13.8 per 100 patients at risk in Cambodia,[12] 29.1 per 1 000 patient days in Indonesia[13] and 14.7 per 1 000 patient days and 21% in Uganda.[14]

    There are limited published data on the antimicrobial management of neonatal and paediatric HAI in SA. Unpublished data from two antibiotic consumption PPSs at Tygerberg Hospital, Cape Town, documented that antibiotic use for treatment of HAI constituted 25% (2012) and 18% (2015) of all paediatric antibiotic consumption, with carbapenems being the most frequently prescribed agents for HAI (Dr Heather Finlayson, personal communication, 1 June 2017). In addition, few studies have documented the availability of infection prevention staff, the suitability of hospital design (e.g. isolation facilities) and the availability of provisions for infection prevention (e.g. hand hygiene consumables) in neonatal and paediatric wards in SA healthcare facilities.[15]

     

    Objective

    We conducted a PPS to document HAI rates, antimicrobial use for HAI, infection prevention staffing, hand hygiene (HH) provisions and HH compliance rates in neonatal and paediatric wards at two district and two regional hospitals in the Western Cape Province, SA.

     

    Methods

    Study setting and design

    We conducted the PPS in the neonatal and paediatric wards at two district hospitals (Karl Bremer (A) and Khayelitsha (B)) and two regional hospitals (Worcester (C) and Paarl (D)) (N=8 wards). The bed complement in the paediatric and neonatal wards (excluding kangaroo mother care wards) at each facility was as follows: A: 30 + 16; B: 32 + 14; C: 18 + 32 and D: 20 + 48. The antenatal HIV prevalence in the Western Cape is 19%, and there is a well-established prevention of mother-to-child HIV transmission programme (<2%HIV transmission in 2015).[16]

    At each facility, a 1-day HAI PPS was conducted, including all patients admitted to the neonatal and paediatric wards at or before 08h00 on the survey day. A standardised paper-based data collection tool was used to collect patient demographics, admission diagnoses, HAI events, current antimicrobial prescriptions and microbiology laboratory results. HAI events that met the 2016 Centers for Disease Control and Prevention (CDC)/National Healthcare Network (NHSN) surveillance definitions were included (both active HAI events and HAI events that had occurred in the preceding 7-day period); additional data were collected on HAI type, pathogen (if known), date of HAI onset and HAI management. On the PPS day, the infection prevention and control (IPC) nurse practitioner at each facility was interviewed regarding practices at their institution (IPC audits/assessments, training and challenges, HAI surveillance methods, and reporting of HAI rates/outbreaks to facility management). An audit of HH provisions and HH compliance was conducted by direct observation in each ward using the World Health Organization (WHO) tool.[17] The ratio of alcohol hand rub and handwash basins to bed capacity was calculated for the neonatal and paediatric wards at each site.

    Study definitions

    The presence and type of HAI event were assessed using the NHSN 2016 definitions and criteria:[1] 'a localized or systemic infective condition in a patient admitted for at least 48 hours (with no evidence that the infection was incubating or present during the time of admission) or a patient who presents with acute infection following a previous health facility admission within the last 30 days'. Bed occupancy (%) was calculated as the number of admitted patients divided by the number of registered neonatal or paediatric beds.

    Antimicrobial use (%) was calculated as the number of children in each ward receiving any oral or intravenous antimicrobial divided by the total number of patients in the ward multiplied by 100. HH compliance (%) was calculated as number of HH actions/number of HH opportunities multiplied by 100; HH compliance was audited on each ward over a 30-minute period. In addition, we documented the availability and functionality of the HH provisions in each neonatal and paediatric ward. For a handwash basin to be considered functional, running water, hand soap and paper towels had to be available at the basin.

    Ethics approval

    Ethics approval and waiver of individual informed consent were granted by the Stellenbosch University Health Research Ethics Committee (ref. no. U16/05/011). The research was approved by the Western Cape Provincial Health Research Committee and the facility manager at each hospital (ref. no. WC_2016RP16_572).

     

    Results

    Of the four hospitals, only one had an IPC nurse practitioner whose time was dedicated to IPC duties; in the other hospitals, these nurses had additional duties including occupational health, quality assurance and sterile services department support (Table 1). All four IPC practitioners reportedly offered frequent in-service training to their facility's staff (at weekly, biweekly or monthly intervals). IPC audits and facility-wide HH audits were conducted at each site at least annually, but only one hospital performed continuous, hospital-wide HAI surveillance. Availability of functional handwash basins and alcohol hand rub was generally adequate, but varied by facility and ward type (neonatal v. paediatric). Few patient isolation rooms were available at any of the sites, and these were mainly located in paediatric wards, with numbers as follows: hospital A: 1 paediatric v. 0 neonatal; hospital B: 1 v. 0; hospital C: 2 v. 2; and hospital D: 3 v. 1.

    A total of 151 patients were present in the eight wards on the PPS day. Overall, 51.7% of the cohort (78/151) were male, 3.3% (5/151) were HIV-infected and receiving antiretroviral therapy, 19.9% (30/151) were HIV-exposed but uninfected, and 11.9% (18/151) were malnourished (5 were severely malnourished, 2 moderately malnourished and 11 underweight for age). Most patients (93.0%) had been admitted directly to the hospital, but 7.2% (n=11) had been transferred in from nearby tertiary hospitals (Groote Schuur, Tygerberg and Red Cross War Memorial) and district hospitals (Robertson and Stellenbosch).

    Average neonatal bed occupancy was 87% (range 72 - 114%), with a mean antimicrobial prescribing rate of 39% (Table 2). The median gestational age for the patients in the neonatal wards (n=57) was 33 weeks (interquartile range (IQR) 28 - 37) and the age range 0 - 38 days. Average paediatric bed occupancy was 66% (range 38 - 91), with a mean antimicrobial prescribing rate of 56% (Table 2). The median age of the patients in the paediatric wards (n=94) was 6 months (IQR 10 days - 2 years). A history of recent hospital admission (discharge in the past 30 days) was documented in 25 (26.6%) of the paediatric patients.

    Overall, 15/151 patients (9.9%; 95% confidence interval (CI) 6 -15.8) had an active HAI event on PPS day; when the 7-day period HAI prevalence definition was used, a further 4 HAI events were identified (19/151, 12.6%; 95% CI 8 - 18.9). HAI event types included HAP (5/15, 33.3%), BSIs (3/15, 20.0%), UTIs (3/15, 20.0%), and one each of surgical site infection, necrotising enterocolitis, conjunctivitis and hospital-acquired gastroenteritis. The prevalence of HAIs was higher among children than neonates (11/94, 11.7% v. 4/57, 7%; p=0.41). Predictors of HAI development in this cohort were recent hospitalisation (8/19, 42.1% v. 17/132, 12.9%; p<0.001) and underlying comorbidity or comorbidities (17/19, 89.4% v. 72/132, 54.5%; p<0.004). Although patients who developed HAI (n=19) had lower median age (33 days (IQR 0 - 108) v. 74 days (IQR 0 - 611)), this difference was not statistically significant.

    All patients who experienced an HAI event were newly initiated on an antimicrobial, the most frequently used empirical antimicrobials for HAI being piperacillin-tazobactam plus amikacin (46.7%, n=7) and third-generation cephalosporins (cefotaxime or ceftriaxone) (26.7%, n=4). Meropenem (n=1), ampicillin (n=1), amoxicillin-clavulanic acid (n=1) and chloramphenicol (n=1) were the antimicrobials used in the remaining HAI events. Appropriate laboratory specimens had been submitted before commencement of empirical antimicrobials in most cases. Potential HAI pathogens were identified from 6/15 specimens submitted (overall yield 40.0%), for bloodstream infections (group B streptococci n=2, Staphylococcus aureus n=1), urinary tract infections (Escherichia coli and Candida albicans n=1 each) and a surgical site infection (Escherichia coli n=1).

    A total of 493 HH opportunities were observed in the eight wards (Fig. 1). HH compliance rates were substantially higher in neonatal wards than paediatric wards (125/243, 51.4% v. 25/250, 10%; p<0.001). Overall HH compliance rates were higher among mothers (45/107, 42.1%) than among nurses (73/263, 27.8%), doctors (29/106, 27.4%) and other staff, including dieticians, radiographers, and speech and hearing therapists (3/17, 17.6%). As assessed using the WHO '5 Moments for Hand Hygiene',[17] the most frequently missed HH opportunities were 'before an aseptic task' (neonates 33.3% v. paediatrics 12.5%) and 'after touching patient surroundings' (neonates 35.9% v. paediatrics 4.7%) (Fig. 2). Overall HH rates per ward type (neonatal v. paediatric) and hospital were as follows: hospital A: 59.3% v. 17.5%; hospital B: 54% v. 10.9%; hospital C 39.3% v. 4.9%; and hospital D: 52.6% v. 6.5%.

     

     

     

     

    Discussion

    This PPS represents the first estimate of HAI burden in neonatal and paediatric wards in SA regional and district hospitals. We documented an HAI point prevalence rate (9.9%) double that reported in a recent Europe-wide neonatal/paediatric HAI PPS, but similar to other LMICs and to that identified by repeated PPS at a tertiary SA children's hospital in 2015/16 (7.4%).[18]

    In agreement with SA and international HAI surveillance studies, predominant HAI types were HAP, HA BSI and UTI.[4,6,7] The proportional contribution of HAP to the overall paediatric HAI burden is likely to be under-represented in this cohort, since the PPS was conducted in a summer month. For most HAI events, appropriate laboratory specimens had been submitted prior to empirical antimicrobial prescriptions. Major HA BSI pathogens in SA include K. pneumoniae and S. aureus[4-9] Although we identified very few bloodstream pathogens in this cohort, 2/3 were group B streptococci bacteraemia events that fulfilled HA BSI criteria but may have represented late-onset maternally derived infection.

    Although HIV infection, HIV exposure and malnutrition were frequent in this cohort, these characteristics were not significantly associated with HAI on univariate analysis, possibly owing to the small PPS sample size. Significant risk factors for HAI development (also described in the Tygerberg cohort[4]) were recent hospitalisation and underlying comorbidity (predominantly prematurity). Development of an HAI prompted a new antimicrobial prescription in all 19 HAI events. HAIs are increasingly recognised as major drivers of inpatient antibiotic consumption and therefore potential contributors to antibiotic resistance. Empirical antibiotic selection for HAI management in this cohort included appropriate agents (piperacillin-tazobactam plus amikacin and third-generation cephalosporins), with no use of carbapenems identified on the PPS day. However, additional longitudinal data on pathogen spectrum and antibiotic susceptibilities are needed from district and regional hospitals to evaluate the appropriateness of empirical HAI treatment regimens, given high prevalence rates of extended-spectrum beta-lactamase (ESBL)-carrying Enterobacteriaceae and methicillin-resistant S.aureus (MRSA).[19] Currently there is no consensus regarding the benchmarking and determination of appropriateness of antibiotic use in neonates and children. Overall neonatal antimicrobial use in our cohort (39%) was similar to a recent worldwide antimicrobial consumption PPS (36.7%),[20] but our paediatric antimicrobial use was substantially higher (56%). However, our paediatric antimicrobial use was lower than that indicated by repeated PPS reporting in Cambodian wards, with a 79% paediatric antimicrobial use.[11]

    HH is a cornerstone of infection prevention in healthcare facilities. In recognising the contribution of HH to patient safety, the WHO launched the 'Clean care is safer care' campaign in October 2005, including guidelines and strategies to increase HH compliance and reduce HAI rates.[21] The WHO reported that 38% of LMICs had poor water and sanitation facilities and theorised that higher rates of HAI in LMICs may be due to poor HH resources.[22] In contrast, we reported high availability of alcohol hand rub and functional handwash basins. A simple and cost-effective strategy to improve HH access and compliance in the neonatal and paediatric wards would be to optimise access to alcohol hand rub even further, providing one bottle of hand rub per bed/cot.

    In keeping with other HH surveillance studies and unpublished annual HH audits at Tygerberg Hospital (Sister Marina Aucamp, personal communication, 30 June 2017), HH compliance rates were substantially higher in neonatal wards compared with paediatric wards.[23-25] Overall HH compliance was highest among mothers, with relatively low compliance by doctors and nurses, particularly in the paediatric wards.

    Behaviour modification and education on the importance of HH for healthcare workers and mothers can potentially improve HH compliance rates. Strategies recommended to improve HH compliance rates at healthcare facilities include optimal access to HH, patient empowerment regarding healthcare workers' HH, monthly HH audits with feedback, consequences for non-compliance with HH recommendations, and continuing education on HH and HAI (E-learning, symposiums and debates). Potential barriers to HH compliance, identified by published focus group discussions with registered nurses, include perceived hand damage and high patient workload.[26] Perceived risk of HAI in a particular patient population (e.g. neonates) may be an important factor in healthcare workers' HH compliance, as suggested by the significantly higher HH compliance rates noted in all four neonatal wards.

    Isolation of patients is an important component in effective IPC, and currently there are limited SA data on paediatric isolation practices.[27] A Tygerberg Hospital-based prospective observational study[27] concluded that 6% of hospitalised patients were isolated (78% for IPC purposes), in comparison with 14 - 17% in high-income countries. The study further highlighted the need for more isolation rooms in low-income settings, particularly for airborne infection transmission prevention (tuberculosis IPC). Although patient isolation rooms were available at each site, no hospital achieved the recommended proportion of isolation beds per ward (2 - 6% actual v. the recommended 20 - 30%).[15]

    Study limitations

    Limitations of this study included the surveillance method used (PPS), which typically under-estimates HAI burden and is affected by seasonality (HAP events were probably under-represented in this cohort, because the PPS was conducted in a summer month), a small sample size which limited the study's power to identify risk factors for HAI, and direct observation with potential to encourage higher HH compliance through the Hawthorne effect.

     

    Conclusions

    HAIs are common and preventable inpatient complications that result in significant morbidity, mortality and healthcare costs. Hospitalised neonates and children are a particularly vulnerable population who should be prioritised for HAI surveillance and prevention programmes. Repeated HAI PPSs in district and regional hospitals could be a feasible and useful method to monitor trends in HAI and the impact of HAI prevention strategies. Given the excellent provision for HH in neonatal/paediatric wards at these hospitals, infection prevention interventions should focus on healthcare worker behaviour modification to improve HH compliance rates.

    Acknowledgements. The authors thank the IPC nurse practitioners at each facility for making themselves available for interviews, as well as the staff and patients at each hospital.

    Author contributions. CO and AD conceptualised the study, collected and analysed data and produced the first draft of the manuscript. HK, NO'C, EvD and MW provided input on study design and critically revised the manuscript. All authors gave final approval of the version to be published.

    Funding. Stellenbosch University Undergraduate Research Fund.

    Conflicts of interest. None.

     

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    Correspondence:
    C Olivier
    courtney_olivier@hotmail.com

    Accepted 4 November 2017