Joan Webster1, Margo A Pritchard2
Background - Methods - Results - Characteristics of Included Studies - References - Data Tables and Graphs
1Centre for Clinical Nursing, Royal Brisbane and Women's Hospital, Brisbane, Australia
2Perinatal Research Centre Women's & Newborn Services, Royal Women's Hospital, Herston, Australia
Citation example: Webster J, Pritchard MA. Gowning by attendants and visitors in newborn nurseries for prevention of neonatal morbidity and mortality. Cochrane Database of Systematic Reviews 2003, Issue 3. Art. No.: CD003670. DOI: 10.1002/14651858.CD003670.
Centre for Clinical Nursing
Royal Brisbane and Women's Hospital
Level 2, Building 34
Butterfield Street
Brisbane
QLD
4029
Australia
E-mail: joan_webster@health.qld.gov.au
| Assessed as Up-to-date: | 11 February 2011 |
|---|---|
| Date of Search: | 17 December 2010 |
| Next Stage Expected: | 11 February 2013 |
| Protocol First Published: | Issue 2, 2002 |
| Review First Published: | Issue 3, 2003 |
| Last Citation Issue: | Issue 3, 2003 |
| Date / Event | Description |
|---|---|
| 11 February 2011 Updated |
This review updates the existing review "Gowning by attendants and visitors in newborn nurseries for prevention of neonatal morbidity and mortality" published in the Cochrane Database of Systematic Reviews (Webster 2009). Updated search found no new trials. No changes to conclusions. |
| Date / Event | Description |
|---|---|
| 06 February 2009 Updated |
This review updates the existing review "Gowning by attendants and visitors in newborn nurseries for prevention of neonatal morbidity and mortality" published in The Cochrane Library Issue 3, 2006 (Webster 2006). |
| 05 April 2006 Updated |
This review updates the existing review of "Gowning by attendants and visitors in newborn nurseries for prevention of neonatal morbidity and mortality" which was published in The Cochrane Library Issue 2, 2003 (Webster 2003). |
| 31 January 2003 New citation: conclusions changed |
Substantive amendment |
Overgowns are widely used in newborn nurseries and neonatal intensive care units. It is thought that gowns may help to prevent the spread of nosocomial infection and serve as a reminder to staff and visitors to wash their hands before contact with the infant.
The objective of this review is to assess the effects of the wearing of an overgown by attendants and visitors on the incidence of infection and death in infants in newborn nurseries.
The standard methods of the Cochrane Collaboration and its Neonatal Review Group were used. We searched the Cochrane Central Register of Controlled Trials (CENTRAL, The Cochrane Library, Issue 1, 2009), MEDLINE (1950 - January 2009), Embase (1950 - January 2009) and CINAHL (1982 - January 2009).
This search was updated in December 2010.
The review includes all published trials using random or quasi-random patient allocation, in which overgowns worn by attendants or visitors were compared with no overgowns worn by attendants or visitors.
The standard methods of the Cochrane Collaboration and its Neonatal Review Group were used. Data extraction and study quality were independently assessed by the two review authors. Missing information was sought from three authors, but only one responded. Results are expressed as relative risk or mean difference with 95% confidence intervals .
Eight trials were included, reporting outcomes for 3,811 infants. Trial quality varied, with only two assessed as being of good quality. Not wearing overgowns was associated with a trend to reduction in the death rate (typical RR 0.84, 95% CI 0.70 to 1.02) compared to wearing overgowns, but these results did not reach statistical significance. There was no statistically significant effect of gowning policy on incidence of systemic nosocomial infection, (typical RR 1.24, 95% CI 0.90 to 1.71). The overall analysis showed no significant effects of gowning policy on the incidence of colonisation, length of hospital stay or handwashing frequency. No trials of visitor gowning were found.
Newborn nurseries and neonatal intensive care units often require staff and visitors to wear overgowns with the intention of preventing the spread of infection. It has also been thought that putting on an overgown will remind people to wash their hands, which is of proven importance in preventing infection. A review of the medical literature identified eight clinical trials on gowning in these settings, involving 3811 newborns. Infection rates, death rates, or the length of stay of infants were not significantly affected by wearing gowns. Only two of the trials were considered to be of good quality, and there was variation between trials regarding gowning policies. Gowning did not increase the rate of handwashing. There is no evidence to support the use of gowning by staff to prevent the spread of infection. Based on these studies, gowning may not be a cost effective policy.
Newborn infants, particularly those admitted to neonatal intensive care units, are at risk for a variety of bacterial, viral and fungal infections (Gaynes 1996). Neonatal infection carries a high risk of morbidity and mortality, especially among very low birth weight infants (Barton 1999). Reasons for higher rates of infection amongst newborns includes their lowered ability to resist disease agents (Levy 1999), exposure to endemic nursery pathogens (Foca 2000; Webster 1994), prolonged use of central venous catheters (Chathas 1990) and exposure to intrauterine infections (Seaward 1998).
Organisms introduced into the nursery may be transmitted to other infants by a variety of routes making cross infection a particular problem (Baltimore 1998). A colonised or infected infant has the potential to impact on the colonisation or infection rates in particular time periods. Handwashing is recognised as the single most effective method of reducing the transmission of microorganisms between patients (Larson 1999) and is an integral part of hospital infection control programs. Other practices, such as various barrier methods, are also used to control cross infection in hospitals. Gowning is one barrier method of infection control frequently used to restrict the transmission of infection (Cloney 1986). It is common practice for attendants and visitors to wear overgowns in some neonatal intensive care nurseries. For attendants, this is to prevent patient-to-patient transmission of microorganisms and infection; for visitors, it is to protect newborns from organisms which they may carry. Although wearing overgowns is believed to increase compliance with hand washing, one non-controlled study has not demonstrated this effect (Donowitz 1987). In recent times, cost considerations have led some institutions to abandon the use of overgowns in newborn nurseries (Thigpen 1991).
Although many centres use overgowns for attendants and visitors as a means of infection control in newborn nurseries and neonatal intensive care units, the benefits and risks of gowning remain unclear.
To determine the effects of wearing overgowns for subgroups of newborn infants by gestational age, by nursery type and by visitors and attendants.
Randomised or quasi-randomised controlled trials in which the unit of allocation is either the individual or a cluster (such as randomisation by physician or hospital or time period).
Use of overgowns compared with no gowns by attendants and visitors in the care of newborn infants.
The standard search strategy of the Cochrane Neonatal Group was used. See: Cochrane Neonatal Group search strategy.
The review authors conducted searches of the Cochrane Central Register of Controlled Trials (CENTRAL, The Cochrane Library, Issue 1, 2009), MEDLINE (1950 - January 2009), Embase (1950 - January 2009), and CINAHL (1982- January 2009), which were published in the English language, using MeSH terms infant- preterm, infant-newborn, cross infection-prevention, cross infection-control, protective clothing and text words neonat*, intensive care unit, nurser* hospital, postpartum, gown*, overgown, covergown, infection*, and colonis*, handwash*. The Oxford Data Base of Perinatal Trials was searched for unpublished trials.
In December, 2010, we updated the search as follows: MEDLINE (search via PubMed), CINAHL, EMBASE and CENTRAL (The Cochrane Library) were searched from 2008 to Dec 2010. Search terms: (cross infection-prevention OR cross infection-control OR protective clothing OR postpartum OR gown* OR overgown OR covergown OR infection* OR colonis* OR handwash*) AND (intensive care unit OR nurser* OR hospital OR nursery OR ER) AND ((infant, newborn[MeSH] OR newborn OR neon* OR neonate OR neonatal OR premature OR low birth weight OR VLBW OR LBW) AND (randomized controlled trial [pt] OR controlled clinical trial [pt] OR randomized [tiab] OR placebo [tiab] OR clinical trials as topic [mesh: noexp] OR randomly [tiab] OR trial [ti]) NOT (animals [mh] NOT humans [mh])). No language restrictions were applied. In addition, clinicaltrials.gov and controlled-trials.com were searched for relevant studies.
The standard methods of the Cochrane Collaboration and its Neonatal Review Group were used.
All randomised and quasi-randomised controlled trials fulfilling the selection criteria described in the previous section were included. Review authors independently assessed whether studies met the inclusion criteria. Results were compared and discrepancies resolved by discussion.
Review authors independently extracted data. Results were compared and discrepancies resolved by consensus or referral to a third party.
The methodological quality of each trial was independently reviewed by each review author taking account of blinding at randomisation, intervention and outcome measurement and completeness of follow up. Additional information was sought from three trial authors. Any disagreement was resolved by discussion. This information was added to the Characteristics of Included Studies table.
In addition, for the update in 2011, the following issues were evaluated and entered into the Risk of Bias table:
If needed, we planned to explore the impact of the level of bias through undertaking sensitivity analyses.
The standard methods of the Neonatal Review Group were used. Statistical analyses were performed using Review Manager software. Categorical data were analysed using relative risk (RR), risk difference (RD) and the number needed to treat (NNT). Continuous data were analysed using weighted mean difference (WMD). The 95% Confidence interval (CI) was reported on all estimates.
Trials which allocated clusters of patients to each intervention were not analysed using the number of clusters as the unit of analysis, as intended in the protocol, but analysed as if the allocation was by individual. This was necessary because none of the authors of these trials used the cluster as the unit of analysis. Analysing cluster trials in this way has the potential to over-estimate the effect of treatment (Mollison 2000). Consequently, for each outcome there is a meta-analysis of all trials and also of two subgroups where appropriate, one which includes the trials which randomised the individual participant and one which includes the cluster allocated trials.
We assessed heterogeneity between results using the I2 statistic (Higgins 2009). This examined the percentage of total variation across studies due to heterogeneity rather than chance. We used a random effects model where the values of I2 were over 50%, indicating a high level of heterogeneity. For all other meta analyses, we used a fixed effect model.
The meta-analysis was performed using Review Manager software (RevMan 5) supplied by the Cochrane Collaboration. For estimates of typical relative risk and risk difference, we used the Mantel-Haenszel method. For measured quantities, we used the inverse variance method. We used a random effects model where the values of I2 were over 50%, indicating a high level of heterogeneity. For all other meta analyses, we used a fixed effect model.
Twelve studies were identified. Four were excluded for the reasons given in the table, Characteristics of Excluded Studies. Eight studies were considered eligible for inclusion in the review. See Table, Characteristics of Included Studies.
Three of the studies randomised by individual infants. Each of these was conducted in a well baby, full-term nursery (Birenbaum 1990; Forfar 1958; Rush 1990). In two of these studies, rooming in was practiced and infants spent only short periods of time in the nursery (Birenbaum 1990; Rush 1990). Methods used in the three studies were similar with staff and visitors in the control arm using gowns and those in the experimental arm not wearing gowns. In both groups, infection control precautions such as handwashing before entering the nursery and before and after handling infants were observed.
Five studies used cluster allocation by alternating blocks of time for the gown and no-gown periods, in either neonatal intensive care or special care nurseries (Agbayani 1981; Evans 1971; Pelke 1994; Silverman 1967; Tan 1995). In the gowning time periods, gowns were worn by all staff and visitors on entering the nursery and for all infant contacts. In the no-gown time periods, there were between study variations in how 'gowning' was defined. In the earlier studies (Agbayani 1981; Evans 1971; Silverman 1967), gowns were not worn when entering the nursery but they were worn if the incubator hood was opened or when an infant was being held. In the two later studies (Pelke 1994; Tan 1995), gowns were not used at all during the no-gown periods. In the Tan 1995 trial, gowns were defined as a plastic apron.
Alternate time periods used in each study were two or three-month blocks and the length of studies varied between eight to 25 months. One study attempted to eliminate exposure effects from one time period to another by excluding infants who were admitted in the last 10 days of each two month interval (Agbayani 1981). Adjustment for seasonal biases was made in a further study where the gowning period was extended for one month at the end of the first 12 months to ensure a different distribution of gowning periods in the second year (Silverman 1967). One study provided evidence of community follow-up to establish if any infections had occurred after hospital discharge (Birenbaum 1990).
Each infant was allocated to the gowning and no-gowning groups according to the gowning policy in place during the month the infant was admitted and outcomes for that infant were attributed to the gowning policy as allocated on admission.
Evans 1971 and Agbayani 1981 reported nasal and umbilical colonisation rates by day of life for the gown and no-gown groups (Evans 1971 on days 2, 4, 6, 8, 10, 14 and 21 and Agbayani 1981 on days 1, 2, 4, 7, 10, 21 and 28). We chose day four results for the meta-analysis to ensure that colonisation was hospital acquired (i.e. acquired more than 48 hours after admission) and to maximise the number included in the sample (i.e. it was not until day 10 when similar days were again used for reporting and by this time, many of the infants had been discharged). Groin swabs were also analysed using day four results (Agbayani 1981).
See: table, Characteristics of Included Studies.
There was adequate concealment of allocation in two of the trials (Birenbaum 1990; Rush 1990), each randomising the individual patient. One used shuffled sealed envelopes (Birenbaum 1990) and the second used consecutively numbered sealed envelopes that contained a folded card with the group allocation (Rush 1990). No information was provided for the allocation technique used by Forfar 1958, but it is stated that infants were randomly assigned to one of two full term nurseries. None of the trials using cluster allocation used randomly allocated periods for the intervention; all use pre-determined two or three month blocks.
Blinding of the intervention was not possible. Blinding of outcome assessment was reported in only one study (Rush 1990).
In the Birenbaum 1990 study, there was no indication of how many infants were randomised on admission to either the gown or no-gown groups. Infants were excluded if they did not have nose and umbilical cultures taken within six hours of delivery or if they did not have cultures taken before discharge. This makes the possibility of attrition bias likely. Rush 1990 enrolled 234 infants in the no-gown group and 239 infants in the gown group. Length of stay was the only outcome calculated using these numbers. Infection and colonisation data were reported on 222 infants and 230 infants respectively. In the Forfar 1958 trial, follow-up data are complete for infection but not for colonisation. There were also incomplete colonisation data in the Agbayani 1981, Evans 1971 and Pelke 1994 trials.
See: List of comparisons
Eight studies met the inclusion criteria and reported on 3,811 infants who were cared for by attendants who wore or did not wear gowns.
The death rate was reported in all the cluster allocation trials, each conducted in intensive care settings (Silverman 1967; Evans 1971; Agbayani 1981; Tan 1995; Pelke 1994). None of the trials found a statistically significant effect on death. The meta-analysis was confined to four trials (Silverman 1967; Evans 1971; Agbayani 1981; Tan 1995). Overall, not wearing a gown was associated with a trend towards reduction in death rate (typical RR 0.84, 95% CI 0.70 to 1.02; typical RD -0.03, 95% CI -0.05 to 0.00), but these results did not reach statistical significance. The death rate as reported by Pelke 1994 was similar between groups (0.44 per 100 patient days in the no gown periods and 0.51 per 100 patient days in the gown periods). Due to the way in which they were reported, these data could not be included in the meta-analysis.
Five cluster allocation trials reported information on systemic infection (septicaemia, meningitis, necrotizing enterocolitis, pneumonia) (Agbayani 1981; Evans 1971; Pelke 1994; Silverman 1967; Tan 1995). One of these (Silverman 1967) reported only meningitis or septicaemia confirmed by postmortem examination. None of the trials found a statistically significant effect on the incidence of systemic nosocomial infection. The meta-analysis, confined to four trials not including Pelke 1994, found no significant effect on systemic nosocomial infection (typical RR 0.95, 95% CI 0.40 to 2.23)]. Substantial heterogeneity was found in this comparison (I2= 57.1%) so a random effects model was used for the meta-analysis. Pelke 1994 also provided data for systemic infections (no gowning period 1.38 infections per 100 patient days; gowning period 1.21 infections per 100 patient days); the difference was not statistically significant. Due to the way in which they were reported, the data of Pelke 1994 could not be included in the meta-analysis.
Four studies were identified that evaluated localised nosocomial infection. Two were trials that randomised the individual patient (Forfar 1958; Rush 1990). These showed no statistically significant effect (typical RR 1.17, 95% CI 0.74 to 1.86). Two were cluster allocation trials Agbayani 1981; Evans 1971). These also showed no significant effect on localised nosocomial infection (typical RR 1.29, 95% CI 0.84 to 2.00). The overall estimate for the four studies showed no significant effect (typical RR 1.24, 95% CI 0.90 to 1.71).
The methods used to collect and process swabs were similar, but the days on which swabs were taken varied between studies. Two of the trials limited their investigation to staphylococcal carriage (Forfar 1958; Rush 1990) and one to methicillin resistant Staphylococcus aureus carriage (MRSA) (Tan 1995). In the Tan 1995 study, the site of colonisation was not noted but carriage rates were similar between groups (no-gown group 4/1002 MRSA positive swabs, gown group 6/904 MRSA positive swabs).
Nasal colonisation data was compared in six of the eight included studies. Three trials that randomised the individual patient (Birenbaum 1990; Forfar 1958; Rush 1990) found no significant differences in nasal colonisation rates (typical RR 1.02, 95% CI 0.89 to 1.18). There was also no significant effect seen in the two cluster trials (Agbayani 1981; Evans 1971) (typical RR 0.91, 95% CI 0.77 to 1.07). When the results of all five trials were combined in an overall meta-analysis, there was no significant effect (typical RR 0.98, 95% CI 0.88, 1.09). In the Pelke 1994 trial the number of swabs taken was used as the denominator with no indication of how many infants were swabbed. There were no significant differences in the rate of positive cultures between the no-gowning and gowning periods (no-gown group 179/375 positive swabs; gown group 208/351 positive swabs).
One study using random allocation by individual (Forfar 1958) collected data on eye colonisation. No significant difference was found between the no-gowned and gowned groups (RR 0.97, 95% CI 0.90 to 1.05).
One of the trials that randomised by individual, reported collected data on groin colonisation (Birenbaum 1990). Gowning policy did not significantly effect this outcome (RR 1.05, 95% CI 0.69 to 1.57).
In one study (Pelke 1994) there was a significant difference in the rate of stool colonisation between the no-gown (84/372) and the gown groups (48/346). A total of 718 cultures were taken from 230 infants, so it is unknown how many repeat cultures were taken from each infant with a positive culture result.
The cost of wearing gowns was estimated in three of the trials. Forfar 1958 included an estimate of the annual cost of gowning (nursing time, cost of gown laundering and maintenance) and calculated that the cost of time alone was equivalent to employing more than one full time equivalent nurse for one year. Tan 1995 compared the cost of gowns used in the no-gowning period with those used in the gowning period. During the gowning period, the average number of gowns used was 312 per day compared with 177 per day in the no-gowning periods. Gowns were defined as plastic aprons and cost Singapore $0.05 each. This resulted in a cost difference of S$1,696 per annum. Rush 1990 concluded that the projected annual cost savings associated with discontinuing gowns would be approximately $US 8,000 per annum.
One cluster allocation trial compared handwashing frequency between the no-gowning and gowning time periods (Pelke 1994). Direct observation at an infant's bedside three times weekly for 30 minutes was used to collect data. A sample of 87 contacts were observed in the no-gowning period and 34 infant contacts during the gowning period. The rate of hand wash compliance was similar in the two groups (no gowning 60%, gowning 62%, p = 0.84).
Length of hospital stay in a well baby nursery was measured in three trials randomising the individual (Birenbaum 1990; Forfar 1958; Rush 1990). In the Rush 1990 study, hospital stay was similar in both groups, (MD 0.40 days, 95% CI -5.82 to 6.62). The number of in-patient days did not differ significantly in either the Forfar 1958 trial (no gown 9.0 days, gown 8.5 days) or the Birenbaum 1990 trial (no gown 2.81 days, gown 2.84 days). Standard deviations were unavailable for these two studies, preventing inclusion of these data in the outcome table.
One cluster allocation trial included results on the duration of mechanical ventilation (Tan 1995). The number of ventilator days was similar for infants admitted during the no-gowning and gowning time periods (MD 5.00 days, 95% CI -11.09 to 21.09).
Pelke 1994 measured length of stay in a neonatal nursery environment. The mean length of stay between the no-gown and gown groups was not statistically different (no-gowning periods: mean number of days = 15; gowning periods: mean number of days = 20).
None of the trials provided data for this outcome
In a cluster allocation trial, Pelke 1994 used two 15-minute observation periods to monitor the number of people entering the nursery. The patterns of traffic were identical during the no-gown and gown periods with an average of 10 entries during each 15-minute observation period.
Post discharge follow-up:
In the Birenbaum 1990 study, 83 from the no-gown group and 81 infants in the gown group were able to be followed up four weeks after discharge. Within this time, one infant from the no-gowning group was treated for conjunctivitis and one infant from the gowning group required hospitalisation for a viral infection.
SUBGROUP ANALYSIS:
All of the trials that randomised the individual patient were conducted in well-baby nurseries and all of the cluster allocation trials were undertaken in neonatal intensive care units. Thus, the analyses of sub-categories for trials randomising the individual are synonymous with well-baby nurseries and sub-categories for cluster allocation trials are synonymous with neonatal intensive care units.
We intended to investigate the effects of wearing gowns for subgroups of newborn infants by gestational age; however, none of the trials reported outcomes specifically by gestational age so this analysis could not be done.
There were no eligible studies reporting the independent effect of visitors or attendants wearing gowns on the study outcomes.
Since overgowns are widely used in neonatal units, it was surprising that the evidence supporting their efficacy was limited. Of the eight studies meeting our inclusion criteria, three used the individual as the unit of allocation, but one of these did not describe the method used for allocation concealment. The nature of the study prevented blinding of the intervention and there was limited reporting of blinding of outcome assessment. Five of the studies had incomplete follow-up data on one or more of the outcomes (Agbayani 1981; Evans 1971; Forfar 1958; Pelke 1994; Rush 1990) and there was evidence of post-randomisation exclusions in one of the trials (Birenbaum 1990). Sample size calculations were absent in all but one study (Rush 1990).
Among the five cluster allocation trials there were a number of methodological variations that made comparisons difficult. In one study, colonisation rates were reported as outcomes per swab rather than per infant, leading to non-independence of multiple measures of the same outcome in the same patient. Similarly, the day on which swabs were routinely taken varied between studies. Rates of colonisation tend to increase with length of hospital stay, so comparing data on this outcome was not feasible unless swabs had been collected on the same postnatal day. Other data were reported as a rate per 100 days making it impossible to combine these results with other outcome data to estimate an overall effect. Although techniques are now available for analysing cluster allocated studies, results were all analysed as if allocation was by individual, ignoring the cluster design and creating a potential to over-estimate the intervention effect. However, based on the consistency of findings between studies, the method of analysis is unlikely to have changed the primary results of this review.
There was little evidence in this review of either harm or benefit of overgown use when outcomes such as systemic infection, localised infection or colonisation were compared. The only important outcome that showed a strong trend in either direction was death before discharge, where the trend was towards a lower death rate among infants nursed in the non-gowning periods. The two studies contributing to the trend were conducted over 30 years ago when death rates in neonatal intensive care units were very high (Evans 1971; Silverman 1967). Both of the studies used a cluster design and analysed results as though allocation was by individual, which may have tended to overestimate treatment effect. In addition, overgowns were worn by attendants and visitors whenever incubator lids were open or if the infant was removed from the cot, making it unlikely that gowning could account for the observed differences. In the most recent and largest trial, no deaths were reported in either the gowning or no-gowning periods (Tan 1995). The one result that showed a significant difference when overgowns were worn or not worn by visitors and attendants was stool colonisation, with a reduction during gown periods. This result was flawed by the study methodology, where there was evidence of repeat measures on the same infant.
Other outcomes such as handwashing frequency, length of hospital stay, duration of mechanical ventilation and traffic in and out of the nursery were not significantly affected by overgown use. Based on these results and considering the costs associated with gowning, hospital personnel may wish to review their policies.
Heterogeneity effected one comparison, systemic infection. This may be explained by some of the issues outlined above, or because there was some variation in outcome when the older studies were compared with more recent investigations.
All the NICU studies included in this review used cluster allocation rather than allocating individual patients to the experimental and control groups. Allocation by cluster might be seen as a strength of study design for this question. It mirrors the way the intervention is offered in practice and minimises contamination of the experimental and control groups. Secondary cases (of colonisation, infection, death) are included in the measure of effect. If a favoured policy is identified in such a study, the application of that result in practice would be to use the favoured policy in all babies, thus mimicking a cluster allocation design. However, future trials which use cluster allocation should use truly random methods for allocating by cluster and should analyse the data taking into account the clustering of allocation.
This systematic review does not provide evidence that overgowns are effective in limiting infant colonisation, infection or death in newborn nurseries. Nor does gowning appear to impact on handwashing frequency. The costs associated with gowning are considerable.
In light of changes in hospital practices (such as rooming in, shortened length of stay and widespread discontinuation of overgown use) since many of the included studies were conducted, further investigations of the effect of overgowns on infection or colonisation rates in well-baby newborn nurseries appear to be unwarranted as their results would not be applicable to current practice.
The question of gowning in neonatal intensive care settings has not been tested using a randomised controlled design. Future investigations in this area should focus on important outcomes such as death and systemic infection using high quality randomised controlled designs of sufficient size to yield a conclusive result. Future studies that use cluster allocation should use truly random rather than quasi-random methods for allocating by cluster, and should analyse the data using methods which take into account the cluster design.
Editorial support of the Cochrane Neonatal Review Group has been funded with Federal funds from the Eunice Kennedy Shriver National Institute of Child Health and Human Development National Institutes of Health, Department of Health and Human Services, USA, under Contract No. HHSN267200603418C.
Joan Webster (JW) conceived the idea for the review and wrote the protocol.
JW and Margo Pritchard (MP) conducted searches independently and agreed on inclusions.
Data was extracted independently by the two review authors.
JW and MP wrote the review.
JW has conducted the updates.
The February 2011 update was conducted centrally by the Cochrane Neonatal Review Group staff (Yolanda Montagne, Diane Haughton, and Roger Soll). This update was reviewed and approved by JW.
| Methods | Single centre cluster-allocation trial. Blinding of randomisation: No. Blinding of intervention: No. Blinding of outcome assessment: Unknown. Completeness of follow-up: |
|---|---|
| Participants | A total of 724 outborn (123) and inborn (601) term and preterm infants. |
| Interventions | No gown: |
| Outcomes | 1) Death before discharge |
| Notes | This trail was analysed as if allocation was by individual. |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | High risk | Single centre cluster-allocation trial Allocation occurred using a pre-established list of 6 alternate 2 month blocks of gowning and modified gowning over a 12-month period |
| Allocation concealment (selection bias) | High risk | Blinding of randomisation: No |
| Blinding (performance bias and detection bias) | Unclear risk | Blinding of intervention: No Blinding of outcome assessment: Unknown |
| Incomplete outcome data (attrition bias) | Unclear risk | Complete for primary outcomes. Incomplete for subgroup of 273 infants. |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre randomised controlled trial. Blinding of randomisation: Yes. Blinding of intervention: Blinding of outcome assessment : Completeness of follow-up: |
|---|---|
| Participants | Drawn from 1218 deliveries with no indication of how many were randomised. Study outcomes were reported for 202 infants. Inclusion criteria: (for 202 infants) Admission to a combination of newborn nursery and rooming in care. |
| Interventions | No gown: |
| Outcomes | 1) Nasal colonisation on admission and on discharge |
| Notes | Strong possibility of post-randomised exclusions (infants who did not have initial cultures within 6 hours of delivery and those who did not have 4 cultures performed). |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Low risk | Single centre randomised controlled trial. Group assignment from shuffled sealed envelopes that designated the gowning or no gowning group. |
| Allocation concealment (selection bias) | Low risk | Blinding of randomisation: Yes |
| Blinding (performance bias and detection bias) | High risk | Blinding of intervention: No Blinding of outcome assessment : Unknown |
| Incomplete outcome data (attrition bias) | Unclear risk | Completeness of follow-up: Unknown. |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre cluster-allocation trial. Blinding of randomisation: No. Blinding of intervention: No Blinding of outcome assessment: Completeness of follow-up: unknown |
|---|---|
| Participants | 604 preterm infants admitted to the premature nursery. |
| Interventions | No gown: Visitors and attendants did not cover their outer clothing and nor did they wash their hands before entering the room. Nurses wore the white uniforms used to travel to the hospital. Those handling newborn infants through ports did not wear gowns but scrubbed for 3 minutes with an antiseptic soap. When infants were removed from an isolette, or when a hood was opened, all persons in the room wore a gown. |
| Outcomes | 1) Death |
| Notes | This trial was analysed as if allocation was by individual. |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Unclear risk | Single centre cluster-allocation trial. Allocation was by alternating 2 or 3 month periods (5 separate gowning periods totaling 11 months and 4 separate non-gowning periods totaling 10 months). One month was excluded from the study |
| Allocation concealment (selection bias) | High risk | Blinding of randomisation: No |
| Blinding (performance bias and detection bias) | Unclear risk | Blinding of intervention: No Blinding of outcome assessment: Unknown |
| Incomplete outcome data (attrition bias) | Unclear risk | Completeness of follow-up: unknown |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre randomised controlled trial. Blinding of randomisation: Unknown. Blinding of intervention: No Blinding of outcome assessment: Unknown. Completeness of follow-up: Localised infection , yes. Colonisation, no |
|---|---|
| Participants | 167 infants admitted to either of two newborn nurseries without rooming in facilities. |
| Interventions | No gowns: |
| Outcomes | 1) Localised nosocomial infection, diagnosed clinically . |
| Notes | Infections were assessed clinically. If possible, a swab was taken from an infected lesion but pathology results were not reported. |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Unclear risk | Single centre randomised controlled trial. Infants were allocated at random to one of two nurseries. No description of the process of random allocation was documented. |
| Allocation concealment (selection bias) | Unclear risk | Blinding of randomisation: Unknown. |
| Blinding (performance bias and detection bias) | High risk | Blinding of intervention: No Blinding of outcome assessment: Unknown |
| Incomplete outcome data (attrition bias) | Low risk | Completeness of follow-up: Localised infection , yes. Colonisation, no |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre cluster-allocation trial: Blinding of randomisation: No. Allocation was by alternate 2-month gowning and no gowning cycles (4 cycles over a period of 8 months). One entire 4 month period was repeated to eliminate the potential for seasonal variables and outbreaks. Blinding of intervention: No Blinding of outcome assessment: Completeness of follow-up: Unclear. The number of cultures exceeded the number of infants but it was unclear if all infants were swabbed. |
|---|---|
| Participants | 313 term and preterm infants admitted to the Neonatal Intensive Care Unit A subgroup of 230 infants (those who had cultures taken) were studied. |
| Interventions | No gown: Nursing staff wore scrub suits, which were home -laundered and worn to the hospital from home. Other visitors and staff wore their street clothes when entering the NICU. Residents were the only group who continued to wear hospital-laundered scrubs and they wore an over-gown when leaving the area. Gowns were available for parents to use when holding their infants but these were not used. |
| Outcomes | 1) Neonatal mortality |
| Notes | This trial was analysed as if allocation was by individual. Infection rates and mortality were reported as 'rate per 100 days'. Information about the numerator and denominator were requested but the author could not provide these details. |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Unclear risk | Single centre cluster-allocation trial: Blinding of randomisation: No. Allocation was by alternate 2 month gowning and no gowning cycles (4 cycles over a period of 8 months). One entire 4 month period was repeated to eliminate the potential for seasonal variables and outbreaks. |
| Allocation concealment (selection bias) | High risk | Blinding of randomisation: No. Allocation was by alternate 2 month gowning and no gowning cycles (4 cycles over a period of 8 months). One entire 4 month period was repeated to eliminate the potential for seasonal variables and outbreaks. |
| Blinding (performance bias and detection bias) | High risk | Blinding of intervention: No Blinding of outcome assessment: Unknown |
| Incomplete outcome data (attrition bias) | Unclear risk | Completeness of follow-up: Unclear. The number of cultures exceeded the number of infants but it was unclear if all infants were swabbed. |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre randomised controlled trial: Blinding of randomisation: Yes, by sealed envelope. Blinding of Intervention: No Blinding of outcome: yes Complete follow- up: No, due to culture reports missing or research staff unavailable to abstract data |
|---|---|
| Participants | 473 infants. Sample drawn from 1130 infants consecutively admitted to a newborn nursery. |
| Interventions | No gown: |
| Outcomes | 1) Nasal colonisation |
| Notes |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Unclear risk | Single centre randomised controlled trial |
| Allocation concealment (selection bias) | Low risk | Blinding of randomisation: Yes, by sealed envelope |
| Blinding (performance bias and detection bias) | High risk | Blinding of Intervention: No Blinding of outcome: Yes |
| Incomplete outcome data (attrition bias) | High risk | Complete follow-up: No, due to culture reports missing or research staff unavailable to abstract data |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre cluster-allocation trial: Blinding of randomisation: No. Allocation was by 12 alternate 2 month periods over a 25 month time frame. At the end of the first year, the standard gowning period was extended for one month to ensure a different distribution of gowning periods in the second year. Blinding of Intervention: No Blinding of outcome: Unknown Complete follow- up: Yes |
|---|---|
| Participants | 745 high risk infants admitted to the special care nursery. Inclusion criteria: birthweight < 2kg, and others with major disorders. Exclusion criteria: infants with diarrhoea. |
| Interventions | No gown: |
| Outcomes | 1) Death |
| Notes | This trial was analysed as if allocation was by individual. |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Unclear risk | Single centre cluster-allocation trial: Allocation was by 12 alternate 2 month periods over a 25 month time frame. At the end of the first year, the standard gowning period was extended for one month to ensure a different distribution of gowning periods in the second year |
| Allocation concealment (selection bias) | High risk | Blinding of randomisation: No |
| Blinding (performance bias and detection bias) | High risk | Blinding of Intervention: No Blinding of outcome: Unknown |
| Incomplete outcome data (attrition bias) | Low risk | Complete follow-up: Yes |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
| Methods | Single centre cluster-allocation trial. Blinding of randomisation: Blinding of Intervention: No Blinding of outcome: Unknown Complete follow- up: Yes |
|---|---|
| Participants | 1906 infants admitted to a neonatal intensive care (212) or special care nursery (1694). |
| Interventions | No gown: |
| Outcomes | 1) Death NB. Outcomes were reported separately by special care or intensive care unit |
| Notes | This trial was analysed as if allocation was by individual. |
| Bias | Authors' judgement | Support for judgement |
|---|---|---|
| Random sequence generation (selection bias) | Unclear risk | Single centre cluster-allocation trial. Allocation was by alternate 2 month periods (6 periods over 12 months) |
| Allocation concealment (selection bias) | High risk | Blinding of randomisation: No |
| Blinding (performance bias and detection bias) | High risk | Blinding of Intervention: No Blinding of outcome: Unknown |
| Incomplete outcome data (attrition bias) | Low risk | Complete follow-up: Yes |
| Selective reporting (reporting bias) | Unclear risk | |
| Other bias | Unclear risk |
Agbayani M, Rosenfeld W, Evans H, Salazar D, Jhaveri R, Braun J. Evaluation of modified gowning procedures in a neonatal intensive care unit. American Journal of Diseases of Children 1981;135:650-2.
Birenbaum HJ, Glorioso L, Rosenberger C, Arshad C, Edwards K. Gowning on a postpartum ward fails to decrease colonization in the newborn infant. American Journal of Diseases of Children 1990;144:1031-3.
Evans HE, Akpata SO, Baki A. Bacteriologic and clinical evaluation of gowning in a premature nursery. Journal of Pediatrics 1971;78:883-6.
Forfar JO, MacCabe AF. Masking and gowning in nurseries for the newborn infant. Effect on staphylococcal carriage and infection. British Medical Journal 1958;1:76-9.
Pelke S, Ching D, Easa D, Melish ME. Gowning does not affect colonization or infection rates in the neonatal intensive care nursery. Archives of Pediatric and Adolescent Medicine 1994;148:1016-20.
Rush J, Fiorina-Chiovitti R, Kaufman K, Mitchell A. A randomized controlled trial of a nursery ritual: wearing cover gowns to care for healthy newborns. Birth 1990;17:25-30.
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Haque KN, Chagla AH. Do gowns prevent infection in neonatal intensive care units. Journal of Hospital Infection 1989;14:159-62.
None noted.
Baltimore RS. Neonatal nosocomial infections. Seminars in Perinatology 1998;22:25-32.
Barton L, Hodgman JE, Pavlova Z. Causes of death in the extremely low birth weight infant. Pediatrics 1999;103:446-51.
Chathas MK, Paton JB, Fisher DE. Percutaneous central venous catheterization. Three years' experience in a neonatal intensive care unit. American Journal of Diseases of Children 1990;144:1246-50.
Cloney DL, Donowitz LG. Overgown use for infection control in nurseries and neonatal intensive care units. American Journal of Diseases of Children 1986;140:680-3.
Donowitz LG. Handwashing technique in a pediatric intensive care unit. American Journal of Diseases of Children 1987;141:683-5.
Foca M, Jacob K, Whittier S, Della Latta P, Factor S, Rubenstein D et al. Endemic pseudomonas aeruginosa infection in a neonatal intensive care unit. New England Journal of Medicine 2000;343:695-700.
Garner JS, Jarvis WR, Emori TG, Horan TC, Hughes JM. APIC Infection Control and Applied Epidemiology: Principles and Practice. St Louis: Mosby, 1996.
Gaynes RP, Edwards JR, Jarvis WR, Culver DH, Tolson JS, Martone WJ. Nosocomial infections among neonates in high-risk nurseries in the United States. National Nosocomial Infection Surveillance System. Pediatrics 1996;98:357-61.
Larson E. Skin hygiene and infection prevention: more of the same or different approaches? Clinical Infectious Diseases 1999;29:1287-94.
Levy O, Martin S, Eichenwald E, Ganz T, Valore E, Carroll SF et al. Impaired innate immunity in the newborn: newborn neutrophils are deficient in bactericidal/permeability increased protein. Pediatrics 1999;104:1327-33.
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Seaward PG, Hannah ME, Myhr TL, Farine D, Ohlsson A, Wang EE et al. International multicentre PROM study: evaluation of predictors of neonatal infection in infants born to patients with premature rupture of membranes at term. Premature Rupture of the Membranes. American Journal of Obstetrics and Gynecology 1998;179:635-9.
Webster J, Pritchard MA. Gowning by attendants and visitors in newborn nurseries for prevention of neonatal morbidity and mortality. Cochrane Database of Systematic Reviews 2003, Issue 3. Art. No.: CD003670. DOI: 10.1002/14651858.CD003670 .
For graphical representations of the data/results in this table, please use link under "Outcome or Subgroup".
| Outcome or Subgroup | Studies | Participants | Statistical Method | Effect Estimate |
|---|---|---|---|---|
| 1.1 Death before discharge | 4 | 2285 | Risk Ratio (M-H, Fixed, 95% CI) | 0.84 [0.70, 1.02] |
| 1.1.1 Trials randomising the individual participant | 0 | 0 | Risk Ratio (M-H, Fixed, 95% CI) | Not estimable |
| 1.1.2 Trials using cluster allocation | 4 | 2285 | Risk Ratio (M-H, Fixed, 95% CI) | 0.84 [0.70, 1.02] |
| 1.2 Systemic nosocomial infection | 4 | 3979 | Risk Ratio (M-H, Random, 95% CI) | 0.95 [0.40, 2.23] |
| 1.2.1 Trials randomising the individual participant | 0 | 0 | Risk Ratio (M-H, Random, 95% CI) | Not estimable |
| 1.2.2 Trials using cluster allocation | 4 | 3979 | Risk Ratio (M-H, Random, 95% CI) | 0.95 [0.40, 2.23] |
| 1.3 Localised nosocomial infection | 4 | 1947 | Risk Ratio (M-H, Fixed, 95% CI) | 1.24 [0.90, 1.71] |
| 1.3.1 Trials randomising the individual participant | 2 | 619 | Risk Ratio (M-H, Fixed, 95% CI) | 1.17 [0.74, 1.86] |
| 1.3.2 Trials using cluster allocation | 2 | 1328 | Risk Ratio (M-H, Fixed, 95% CI) | 1.29 [0.84, 2.00] |
| 1.4 Nasal colonisation | 5 | 1122 | Risk Ratio (M-H, Fixed, 95% CI) | 0.98 [0.88, 1.09] |
| 1.4.1 Trials randomising the individual participant | 3 | 787 | Risk Ratio (M-H, Fixed, 95% CI) | 1.02 [0.89, 1.18] |
| 1.4.2 Trials using cluster allocation | 2 | 335 | Risk Ratio (M-H, Fixed, 95% CI) | 0.91 [0.77, 1.07] |
| 1.5 Umbilical colonisation | 5 | 1116 | Risk Ratio (M-H, Fixed, 95% CI) | 1.01 [0.93, 1.10] |
| 1.5.1 Trials randomising the individual participant | 3 | 781 | Risk Ratio (M-H, Fixed, 95% CI) | 1.03 [0.93, 1.14] |
| 1.5.2 Trials using cluster allocation | 2 | 335 | Risk Ratio (M-H, Fixed, 95% CI) | 0.96 [0.82, 1.12] |
| 1.6 Eye colonisation | 1 | 159 | Risk Ratio (M-H, Fixed, 95% CI) | 0.97 [0.90, 1.05] |
| 1.6.1 Trials randomising the individual participant | 1 | 159 | Risk Ratio (M-H, Fixed, 95% CI) | 0.97 [0.90, 1.05] |
| 1.6.2 Trials using cluster allocation | 0 | 0 | Risk Ratio (M-H, Fixed, 95% CI) | Not estimable |
| 1.7 Groin colonisation | 1 | 200 | Risk Ratio (M-H, Fixed, 95% CI) | 1.05 [0.69, 1.57] |
| 1.7.1 Trials randomising the individual participant | 1 | 200 | Risk Ratio (M-H, Fixed, 95% CI) | 1.05 [0.69, 1.57] |
| 1.7.2 Trials using cluster allocation | 0 | 0 | Risk Ratio (M-H, Fixed, 95% CI) | Not estimable |
| 1.8 Length of hospital stay | 1 | 473 | Mean Difference (IV, Fixed, 95% CI) | 0.40 [-5.82, 6.62] |
| 1.8.1 Trials randomising the individual participant | 1 | 473 | Mean Difference (IV, Fixed, 95% CI) | 0.40 [-5.82, 6.62] |
| 1.8.2 Trials using cluster allocation | 0 | 0 | Mean Difference (IV, Fixed, 95% CI) | Not estimable |
| 1.9 Duration of mechanical ventilation | 1 | 212 | Mean Difference (IV, Fixed, 95% CI) | 5.00 [-11.09, 21.09] |
| 1.9.1 Trials randomising the individual participant | 0 | 0 | Mean Difference (IV, Fixed, 95% CI) | Not estimable |
| 1.9.2 Trials using cluster allocation | 1 | 212 | Mean Difference (IV, Fixed, 95% CI) | 5.00 [-11.09, 21.09] |