David A Osborn1, Nicholas J Evans2
Background - Methods - Results - Characteristics of Included Studies - References - Data Tables and Graphs
1RPA Newborn Care, Royal Prince Alfred Hospital, Camperdown, Australia
2Neonatal Medicine, Royal Prince Alfred Hospital, Camperdown, Australia
Citation example: Osborn DA, Evans NJ. Early volume expansion for prevention of morbidity and mortality in very preterm infants. Cochrane Database of Systematic Reviews 2004, Issue 2. Art. No.: CD002055. DOI: 10.1002/14651858.CD002055.pub2.
RPA Newborn Care
Royal Prince Alfred Hospital
Missenden Road
Camperdown
New South Wales
2050
Australia
E-mail: david.osborn@email.cs.nsw.gov.au
Assessed as Up-to-date: | 31 July 2008 |
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Date of Search: | 31 July 2008 |
Next Stage Expected: | 31 August 2010 |
Protocol First Published: | Issue 2, 2000 |
Review First Published: | Issue 2, 2001 |
Last Citation Issue: | Issue 2, 2004 |
Date / Event | Description |
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31 July 2008 Updated | This review is an update of the existing review "Early volume expansion for prevention of morbidity and mortality in very preterm infants", published in the Cochrane Database of Systematic Reviews, Issue 2, 2004 (Osborn 2004). Our updated literature search found a publication of study previously reported in abstract form only. Several studies did not meet eligibility criteria. Background updated and review updated to include outcomes from new publication. No changes in conclusions. |
20 April 2008 Amended | Converted to new review format. |
Date / Event | Description |
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06 February 2004 New citation: conclusions not changed | This review is an update of the existing review "Early volume expansion for prevention of morbidity and mortality in very preterm infants", published in The Cochrane Library, Issue 3, 2001 (Osborn 2001). |
Reduced perfusion of organs such as the brain, heart, kidneys and the gastrointestinal tract may lead to acute dysfunction and be associated with permanent injury. Various strategies have been used to provide cardiovascular support to preterm infants including inotropes, corticosteroids and volume expansion.
To determine the effect of early volume expansion on morbidity and mortality in very preterm infants. If volume expansion is effective, to determine the type of volume expansion that is most effective.
The standard search strategy of the Neonatal Review Group was used. Updated searches were performed of the Cochrane Central Register of Controlled Trials (Issue 3, 2008), MEDLINE (1996 - July 2008), EMBASE (1980 - July 2008), previous reviews including cross references, abstracts and conferences.
Randomised trials of early volume expansion with normal saline, fresh frozen plasma, albumin, plasma substitutes or blood compared to no treatment or another form of volume expansion in preterm infants ≦ 32 weeks gestation or ≦ 1500 g were included. Volume expansion was defined as at least 10 ml/kg given in the first 72 hours after birth.
Standard methods of the Neonatal Review Group with use of relative risk (RR), risk difference (RD) and weighted mean difference (WMD). The fixed effects model was used for meta-analysis. Data from individual studies were only eligible for inclusion if a least 80% of infants were reported for that outcome.
Eight studies were included. Five studies compared volume to no treatment. Most studies enrolled very preterm infants on the basis of gestation or birthweight. Two studies comparing different types of volume expansion enrolled very preterm infants with hypotension. No study enrolled infants on the basis of low blood flow. One study examined the effect of volume expansion on blood flow, but evaluated normotensive very preterm infants.
Four studies comparing volume expansion and no treatment with a total of 940 very preterm infants reported no significant difference in mortality (typical RR 1.11, 95% CI 0.88, 1.40). The large NNNI 1996 study reported no significant difference in severe disability (RR 0.80, 95% CI 0.52, 1.23), cerebral palsy (RR 0.76, 95% CI 0.48, 1.20) and combined death or severe disability (RR 1.00, 95% CI 0.80, 1.24). Although one small study (Beverley 1985) reported reduced P/IVH with volume expansion, this was not supported by any other study. No significant difference was reported in grade 3-4 P/IVH and combined death or grade 3-4 P/IVH. One study (NNNI 1996) reported no significant difference in the incidence of hypotension. The finding of decreased necrotising enterocolitis and increased sepsis in infants who received fresh frozen plasma compared to no treatment in one study should be treated with caution. No significant differences in mortality or disability were found in this study. Comparing albumin and saline in hypotensive infants, one study (Lynch 2008) reported a significant increase in mean BP and reduced incidence of treatment failure (persistent hypotension treated with dopamine). The other study (So 1997) and the meta-analysis of the two studies found no significant difference in treatment failure (typical RR 0.76, 95% CI 0.54, 1.07) or in any other clinical outcome.
There is no evidence from randomised trials to support the routine use of early volume expansion in very preterm infants without cardiovascular compromise. There is insufficient evidence to determine whether infants with cardiovascular compromise benefit from volume expansion. There is insufficient evidence to determine what type of volume expansion should be used in preterm infants (if at all) or to determine the benefit of using early red cell transfusions. The significance of the finding of a significant increase in blood pressure in hypotensive preterm infants in one trial comparing albumin and saline is unclear, but the overall meta-analyses found no other significant clinical benefit in using albumin compared to saline.
Early volume expansion for very preterm babies has not been shown to improve their outcomes but more research is needed. Low blood pressure and blood flow have been linked to brain injury in preterm babies. They can also cause permanent injury to other organs and developmental problems. One way of trying to increase the blood pressure and flow of blood is to increase the amount of fluid in the blood stream (volume expansion). This can be done with products such as albumin (a protein) and salt solutions. The review of evidence from trials found that volume expansion has not been shown to improve outcomes for preterm babies. More research is needed.
Reduced perfusion of organs such as the brain, heart, kidneys and the gastrointestinal tract may lead to acute dysfunction and be associated with permanent injury. Twenty percent of surviving babies born very premature do so with some degree of neurodevelopmental disability (Lorenz 1998). Low systemic blood pressure (BP) and systemic blood flow (SBF) have both been linked to cerebral injury in preterm infants. Systemic arterial hypotension is associated with peri/intraventricular haemorrhage (P/IVH), ischaemic cerebral lesions and poor
long-term neurodevelopmental outcome (Miall-Allen 1987; Goldstein 1995; Low 1993). Low upper body blood flow (Kluckow 2000; Osborn 2003; Miletin 2008) and low cerebral blood flow (Meek 1999) on the first day after birth are associated with late P/IVH. In addition, low upper body blood flow on the first day (as measured by flow in the superior vena cava) was associated with a significant increase in mortality (Osborn 2003; Kluckow 2000), necrotising enterocolitis (Osborn 2007) and subsequent neurodevelopmental impairment (Hunt 2004; Osborn 2007) in infants born < 30 weeks' gestation.
Clinical features suggesting reduced perfusion include low BP, reduced cutaneous perfusion and metabolic acidosis. However, systemic arterial pressure has been shown to be poorly correlated with SBF as measured by Doppler ultrasound in preterm infants (Kluckow 1996; Kluckow 2000; Osborn 2004a). In addition, clinical measures of hypovolaemia including systemic hypotension have been found to be poorly correlated to blood volume in premature infants (Barr 1977; Bauer 1993).
Various therapeutic strategies have been used to provide cardiovascular support to preterm infants including inotropes, corticosteroids and volume expansion. Most strategies have targeted low BP using inotropes such as dopamine vs. dobutamine (Greenough 1993; Hentschel 1995; Klarr 1994; Roze 1993), dopamine vs. adrenaline (Pellicer 2005; Valverde 2006), corticosteroids (Gaissmaier 1999), and corticosteroids vs. dopamine (Bourchier 1997). Trials of dopamine vs. dobutamine in very preterm infants with systemic hypotension have not found a difference between these inotropes at preventing mortality and P/IVH. Dopamine was more effective than dobutamine at treating systemic hypotension in very preterm infants (Subhedar 2003). Despite an increase in systemic BP, dopamine was shown to reduce aortic blood flow in one study (Roze 1993). In another study in very preterm infants with low SBF, dobutamine which produced little change in BP but a significantly greater increase in SBF than dopamine, despite dopamine resulting in a significantly greater increase in BP (Osborn 2002). However, there was no significant difference in long-term outcomes (Osborn 2007; Osborn 2007a). Strategies to correct systemic hypotension and hypovolaemia have also included volume expansion. Observational studies have found increases in cardiac output after albumin infusion in sick preterm infants (Pladys 1997) and a small increase in systemic BP in hypotensive preterm infants (Barr 1977; Bignall 1989). Short-term increases in SBF have also been reported after saline infusion in preterm infants with low SBF (Osborn 2002). Observational studies have also reported an increase in P/IVH (Goldberg 1980) and chronic lung disease (Van Marter 1990) in preterm infants receiving volume expansion. A systematic review of randomised controlled trials of albumin infusions in critically ill patients including those with hypovolaemia, burns and hypoalbuminaemia found a significantly increased mortality for those patients receiving albumin compared to control (Alderson 2004).
The question addressed by this review is what is the evidence from randomised controlled trials for the use of early volume expansion to prevent mortality and morbidity in very preterm infants. In view of the difficulties of identifying infants with poor perfusion and hypovolaemia, subgroup analysis was planned according to method of diagnosis of poor perfusion (unselected preterm infants, preterm infants with clinical indicators of poor perfusion [low BP, reduced cutaneous perfusion and metabolic acidosis] and infants with ultrasound Doppler detected low blood flow). As there is evidence to suggest that late intraventricular haemorrhage is associated with systemic hypotension and low SBF in the first day of life (Miall-Allen 1987; Goldstein 1995; Kluckow 2000; Osborn 2003), subgroup analysis was performed with the hypothesis that trials that used early volume expansion were more likely to prevent intraventricular haemorrhage. As different volume expanders have different effects, subgroup analysis was performed according to type of volume expansion used. This is an update of a previous Cochrane Review (Osborn 2001; Osborn 2004).
To determine the effect of early volume expansion on morbidity and mortality in very preterm infants. Subgroup analysis was planned according to method of diagnosis of poor perfusion (unselected preterm infants, preterm infants with clinical indicators of poor perfusion and infants with ultrasound Doppler detected low blood flow), postnatal age of treatment and type of volume expansion used. In trials among such infants which compare two or more different types of infusate for volume expansion, to determine which type of volume expansion is more effective.
Randomised controlled trials that compare volume expansion with control (no treatment), and randomised controlled trials comparing two or more types of infusate for volume expansion. Trials with adequate randomisation and ≧ 80% follow-up of participants were eligible for inclusion.
Very preterm infants born ≦ 32 weeks' gestation or ≦ 1500 g and enrolled and treated in the first 72 hours after birth. Trials were eligible if they enrolled either unselected preterm infants, preterm infants with clinically suspected poor perfusion (eg. low BP, poor cutaneous perfusion, or metabolic acidosis), or preterm infants with low blood flow (eg. determined by Doppler ultrasound). Low BP may be defined as BP either less than a specified percentile of a standard chart, a mean BP ≦ 30 mmHg in any preterm infant or a mean BP ≦ 1 mmHg per week of gestation.
Volume expansion including normal saline, fresh frozen plasma, albumin, plasma substitute or blood. Volume expansion was defined as at least 10ml/kg additional volume above maintenance requirements given over less than 6 hours.
Primary outcome measures included any of the following:
Secondary outcome measures included any of the following;
Planned subgroup analyses included the following identified subcategories:
All primary and secondary outcomes were included in subgroup analysis where available.
An updated search was performed of Cochrane Central Register of Controlled Trials (CENTRAL, The Cochrane Library Issue 3, 2008), MEDLINE (1996 - July 2008), EMBASE (1980 - July 2008), previous reviews including cross references (all articles referenced), abstracts and conferences (Perinatal Society of Australia and New Zealand, and Pediatric Academic Societies and American Academy of Pediatrics meetings 2004 - 2008). The previously documented search strategy was expanded to include MeSH terms "[polygeline or albumins]" and text words "[starch or albumin or albumen or gelofusine or plasma]"
This review updates a previous version (Osborn 2004). For all versions, the standard search strategy of the Neonatal Review Group was used. The original review (Osborn 2001) included searches of the Oxford Database of Perinatal Trials. The January 2004 update included searches of CENTRAL (The Cochrane Library Issue 1, 2004), MEDLINE (1996 - January 2004), EMBASE (1980 - January 2004), previous reviews including cross references (all articles referenced), abstracts and conferences (Perinatal Society of Australia and New Zealand, and Pediatric Academic Societies and American Academy of Pediatrics meetings 1998 - 2003). The search of MEDLINE included both MeSH searches using the following terms ("[colloids or plasma substitutes or sodium chloride or serum albumin or hypotension] and infant-premature") and text searches using the following words ("[colloid or crystalloid or saline or volume or hypotension] and infant-premature"). No language restriction was used.
Criteria and methods used to assess the methodological quality of the included trials: Standard methods of the Cochrane Collaboration and its Neonatal Review Group were used. The methodological quality of each trial was reviewed independently by the second review author. Particular emphasis was placed on allocation concealment, blinding, completeness of follow up and blinding of outcome assessment. Allocation concealment was ranked: Grade A: adequate; Grade B: uncertain; Grade C: clearly inadequate. Additional information was requested from authors of each trial to clarify methodology (see 'table of included studies' - 'notes').
Methods used to collect data from the included trials: Each review author extracted data separately then compared and resolved differences. Additional data where required was requested from authors of trials (see 'table of included studies' - 'notes').
Methods used to synthesise the data: Standard methods of Neonatal Review Group with use of relative risk and weighted mean difference where appropriate. The fixed effects model using RevMan 5.0 was used for meta-analysis. Heterogeneity was explored using funnel plots and the chi2 statistic for heterogeneity, and quantified using the I2 statistic. Sensitivity analysis was performed on the basis of methodological quality.
Eight studies were eligible for inclusion (see 'table of included studies'). An additional published report was found for one study (Lynch 2008). Data from a previously unpublished study was not provided by the author and is now listed as an excluded study (Wright 1995).
Infants: The largest study was the NNNI 1996 study with 776 enrolled infants. The other studies were all small with between 25 and 102 infants randomised. Infant numbers, weights and gestations are documented in the table "Characteristics of Included Studies'. Four studies enrolled very preterm infants on the basis of prematurity or low birth weight, not on the basis of haemodynamic compromise (Beverley 1985; Ekblad 1991; Gottuso 1976; NNNI 1996). Emery 1992 enrolled infants with a systolic BP < 40 mmHg. Infants with clinical volume overload were excluded. Infants in the study by Lundstrom 2000 were enrolled if the mean BP was in the normal range (29 - 40 mmHg) and they had not received volume or inotrope in the preceding three hours. The authors state that this group were considered to be above the presumed normal upper limit for hypotension but from previous work may still be at risk of low left ventricular output and cerebral blood flow. Lynch 2008 enrolled hypotensive preterm infants before three days of age and with mean BP < 5th percentile. So 1997 enrolled mechanically ventilated preterm infants with hypotension (low mean BP according to birthweight strata).
Interventions: Beverley 1985 compared fresh frozen plasma 10 ml/kg on admission and repeated at 24 hours of age to no treatment. Ekblad 1991 compared fresh frozen plasma 10 ml/kg (given over three hours at < 5 hours of age, then daily for 3 days) to no treatment. Emery 1992 compared fresh frozen plasma to albumin 4.5% (15 ml/kg over three hours) given to infants on day one to four after birth. A control group given albumin 20% 5 ml/kg is not included in this review. Gottuso 1976 compared fresh frozen plasma 15 ml/kg to no treatment (supportive care only) in infants < 24 hours of age. Lundstrom 2000 compared albumin 20% 15 ml/kg to no treatment in infants with a mean postnatal age of 32 hours (range 5 - 224). Lynch 2008 compared albumin 10 ml/kg with normal saline 10ml/kg infused over 20 minutes in infants < 3 days of age. Volume was repeated if hypotension persisted. The NNNI 1996 study compared infants < 2 hours of age randomised to either fresh frozen plasma 15 ml/kg, a gelatin-based plasma substitute (Gelofusine) 20 ml/kg (given over 15 minutes and repeated after 24 hours) or to no treatment. So 1997 compared infants randomised to albumin 5% or normal saline 10 ml/kg over 30 minutes, with a maximum of three doses given if hypotension persisted.
Outcomes: the stated primary outcomes for the studies included P/IVH (Beverley 1985), water balance and renal function (Ekblad 1991), systolic BP one and four hours after infusion (Emery 1992), haemodynamic change (mean BP, left ventricular output and cerebral blood flow) (Lundstrom 2000), improvement in arterial BP to normal (> 10th percentile for mean BP for weight) at one hour after infusion (Lynch 2008), death before discharge or severe disability at two years (NNNI 1996) and successful treatment of hypotension (So 1997). The data for treatment failure in the studies by Lynch 2008 and So 1997 are the number of infants with persistent hypotension after volume therapy requiring inotropes. Gottuso 1976 did not state a primary outcome but measured mortality and blood gas data. Data from the NNNI 1996 study for grade 1 P/IVH, grade 2 - 4 P/IVH and periventricular leucomalacia were available from a subgroup of units with routine scan facilities. Data from this study for grade 3 - 4 P/IVH included late cystic parenchymal lesions. The data for severe neurodevelopmental disability included children who were blind, deaf, unable to walk, had a developmental quotient > 3 SD below mean or another severe disability. Hypotension in the NNNI 1996 study was defined as systolic BP < 35 mmHg. Treatment failure in this study was defined as the occurrence of hypotension on the first day after birth and was only available for a subgroup of infants born in 1990 and 1991.
In this update, the number of excluded reports has increased from 37 to 46 (see 'Characteristics of Excluded Studies'). These included 11 studies which had no control group (Alkalay 1999; Barr 1977; Bauer 1993; Belgaumkar 1998; Bignall 1989; Dimitriou 2001; Lambert 1998; Lay 1980; Nelle 1997; Pladys 1994; Pladys 1997; Sriram 1997). Three studies used insufficient volume to be eligible for inclusion, with less than 10 ml/kg volume given (Bland 1976; Greenough 1993; McMurray 1948). One of these also enrolled infants with a mean gestational age > 32 weeks (Bland 1976). One study enrolled term infants with suspected asphyxia (Gurkan 2000). Several studies treated infants predominately after the first 72 hours (Liet 2003; Liet 2006; McMurray 1948; Paul 2003; Upadhyay 2005). Four studies of red cell transfusion were in infants > 3 days old (Beeram 2003; Blank 1984; Meyer 1993; Nose 1996) and two studies (Paul 2002; Wong 2005) compared the effect of different red cell transfusion volumes in preterm infants with a low hematocrit. One study printed in abstract form only did not state volume of fresh frozen plasma given and data for analysis could not be extracted (Alexander 1976). Oca 2003 comparing volume expansion with albumin to normal saline enrolled hypotensive infants stratified by birth weight < 2500 g or > 2500 g. There were excess losses (23%) in the < 2500g strata to meet eligibility for inclusion in the review.
See the table 'Characteristics of included studies'.
Seven studies reported adequate randomisation procedures and had adequate allocation concealment (Beverley 1985; Emery 1992; Gottuso 1976; Lundstrom 2000; Lynch 2008; NNNI 1996; So 1997). One study did not report the method of randomisation (Ekblad 1991). Lynch 2008 reported 'blinding' by sending the allocated solution from pharmacy in an opaque bag. No other study stated that the interventions were blinded in any way. Given the nature of the interventions, it is probable that caregivers were not blinded in any of the studies. Blinding measurement of outcomes was reported by Beverley 1985 (P/IVH), Lynch 2008 (all outcomes) and the NNNI 1996 study (neurodevelopmental assessment). Studies reporting no losses to follow-up included Emery 1992; Gottuso 1976; Lundstrom 2000; NNNI 1996 study (neurodevelopmental assessment) and So 1997. Beverley 1985 reported seven (12.5%) losses. Data for P/IVH for the excluded infants is available and used in the analysis of mortality and P/IVH in this review. Ekblad 1991 reported outcomes for the same cohort of infants in two papers, with data reported on 38 of 40 infants in one paper (PDA) and 35 of 40 (renal function) in the other. Data for P/IVH and mortality for the excluded infants is available and used in the analysis of these outcomes in this review. The grade of P/IVH was not available for the excluded infants. The authors have been contacted to obtain this information. Data for PDA were not available for two infants. Lynch 2008 did not report post-randomisation losses so losses are unclear. Lynch 2008 also reported PIVH for a subset of infants born < 1500g. Not all units in the NNNI 1996 study performed routine head ultrasound scans. Data for P/IVH were available for approximately 84% of 611 infants from centres with routine scan facilities. The NNNI 1996 study reported head ultrasound abnormalities in units with routine scanning facilities as intraventricular haemorrhage and periventricular abnormality in babies surviving at six weeks. This was then reclassified into subependymal haemorrhage, more severe haemorrhage, any cerebral abnormality, severe cerebral abnormality, and death or severe cerebral abnormality. Approximately 84% of surviving infants had data from both one and six weeks' ultrasounds. Only data from this subgroup of units with > 80% follow-up and from surviving infants with both one and six weeks scans have been used in this review.
As the ascertainment of head ultrasound abnormality was different between the studies, data for P/IVH, grade 2 - 4 P/IVH, grade 3 - 4 P/IVH and periventricular leucomalacia are only combined in meta-analysis in studies that report similar methods of ascertainment. Data are included where there is > 80% ascertainment of infants for the outcome.
Primary outcomes: Five studies randomised infants to volume vs. no treatment in very preterm infants (Beverley 1985; Ekblad 1991; Gottuso 1976; Lundstrom 2000; NNNI 1996). Four studies with a total of 940 infants reported mortality (Beverley 1985; Gottuso 1976; Lundstrom 2000; NNNI 1996). None found a significant effect. Meta-analysis showed the mortality was similar for infants who received volume compared to no treatment (typical relative risk 1.11, 95% confidence intervals 0.88, 1.40; typical risk difference 0.02, 95% CI -0.03, 0.08) (Outcome 1.1). Two of these studies (Beverley 1985; Ekblad 1991) reported P/IVH data on all infants randomised. Beverley 1985 found a significant reduction in P/IVH (RR 0.46, 95% CI 0.21, 0.98) whereas Ekblad 1991 found no significant difference (RR 1.21, 95% CI 0.31, 4.71). Meta-analysis of these 2 studies showed no significant difference in P/IVH (typical RR 0.58, 95% CI 0.30, 1.11; typical RD -0.14, 95% CI -0.29, 0.01) (Outcome 1.2). Beverley 1985 found no significant difference in grade 2 - 4 P/IVH (RR 0.43, 95% CI 0.17, 1.08) or grade 3-4 P/IVH (RR 0.55, 95% CI 0.21, 1.47); the difference in rate of death or P/IVH was of borderline significance (RR 0.55, 95% CI 0.30, 1.03; RD -0.21, 95% CI -0.42, -0.01). There was no significant difference in death or grade 3 - 4 P/IVH (RR 0.68, 95% 0.32, 1.46). For the 413 survivors who were examined at six weeks in centres with routine scan facilities in the NNNI 1996 study, no significant difference was found in P/IVH in survivors (RR 1.05, 95% CI 0.75, 1.47) or grade 2 - 4 P/IVH in survivors (RR 1.03, 95% CI 0.55, 1.90). For the 611 infants randomised in these units, there was no difference in death or P/IVH (RR 1.04, 95% CI 0.83, 1.29) and death or grade 3-4 P/IVH (RR 1.12, 95% CI 0.84, 1.49). Lundstrom 2000 reported no infants with periventricular leucomalacia in either group. In the 413 survivors examined, the NNNI 1996 study found no significant difference in periventricular leucomalacia (RR 0.69, 95% CI 0.40, 1.20). The NNNI 1996 study reported long-term neurodevelopmental outcome in survivors. There was no significant difference in severe disability (RR 0.80, 95% CI 0.52, 1.23), cerebral palsy (RR 0.76, 95% CI 0.48, 1.20) and death or severe disability (RR 1.00, 95% CI 0.80, 1.24).
Secondary outcomes: The NNNI 1996 study found no significant difference in the rates of treatment failure for a subgroup of infants born 1990-91 (hypotension: RR 0.55, 95% CI 0.24, 1.28) or in transient renal impairment (data not given in paper). Ekblad 1991 (2 infants lost from analysis) found an increase in PDA of borderline significance (RR 1.62, 95% CI 1.00, 2.62; RD 0.33. 95% CI 0.05, 0.61). Beverley 1985 found no difference in PDA (RR 1.14, 95% CI 0.53, 2.48). Meta-analysis of the two studies found no significant difference in PDA (typical RR 1.39, 95% CI 0.91, 2.14) (Outcome 1.12). There was no significant difference in rates of pneumothorax, necrotising enterocolitis, or sepsis (Outcomes 1.13 - 1.15). One study (Lundstrom 2000) found a non-significant trend for volume to increase left ventricular output (mean difference 26.6 ml/kg/min, 95% CI -1.7, 69.9) and cerebral blood flow (MD 7.8 ml/kg/min, 95% CI -19.8, 35.4) compared to a control group, but to have little effect on mean BP (MD 6.8 mmHg, 95% CI -16.8, 30.4). No data were available for incidence of low blood flow, use of additional inotropes or retinopathy.
No studies were found that compared early red cell transfusion to a control group. No study reported any primary outcomes for the comparison of albumin and fresh frozen plasma.
Primary outcomes: Two studies (So 1997; Lynch 2008) compared volume expansion using albumin 5% to normal saline 10ml/kg in hypotensive preterm infants. Meta-analysis found no significant difference in mortality (typical RR 1.02; 95% CI 0.50, 2.06) (Outcome 2.1). Neither study reported a significant difference in PIVH or PIVH grade 3 - 4, although the was substantial but not statistically significant heterogeneity in both analyses. Meta-analysis found no significant difference in P/IVH (typical RR 0.95; 95% CI 0.56, 1.61) and grade 3 - 4 P/IVH (typical RR 0.77; 95% CI 0.30, 1.95) (Outcomes 2.2, 2.3). No data were available for periventricular leucomalacia or long-term disability.
Secondary outcomes: One study (Lynch 2008), reported a significant reduction in treatment failure (persistent hypotension requiring inotropes (RR 0.54; 95% CI 0.30, 0.97) in infants receiving albumin compared to normal saline. So 1997 reported no significant difference in treatment failure (RR 1.02, 95% CI 0.68, 1.55). Meta-analysis found no significant difference in treatment failure (two studies,163 infants; typical RR 0.76, 95% CI 0.54, 1.07) (Outcome 2.4). There was substantial (I2 70%) heterogeneity of borderline significance (chi2 p = 0.07). So 1997 reported no significant difference in chronic lung disease (oxygen requirements at 28 days or 36 weeks postmenstrual age), patent ductus arteriosus, necrotising enterocolitis and sepsis (Outcomes 2.5 - 2.8). No data were available for retinopathy.
Other outcomes: Lynch 2008 reported (in abstract) a significantly greater increase in mean BP in infants receiving albumin compared to normal saline (MD 9.9%, 95% CI 1.22-18.58). Lynch 2008 reported no significant difference in infants receiving a second bolus (albumin 61.2% vs. saline 64.7%), urine output (ml/kg/hr) for six hours after the first bolus (1.7 ± 2.2 vs. 1.8 ± 2) or cost of therapy per patient including pharmacy and nursing costs (albumin $US63.98 ± 8.03 vs. saline $US62.18 ± 8.58). So 1997 reported no significant difference in mean arterial BP (data presented in article in figure) but infants who received albumin received a significantly increased amount of extra volume for hypotension (mean 27.5 vs. 10.0 ml, p = 0.02) and had a significantly greater increase in weight in the first 48 hours (5.9 +\- 1.9% vs. 0.9 +\- 1.7%, p = 0.05).
See 'Colloid vs. crystalloid' above.
Primary outcomes: One study randomised 25 normotensive preterm infants to albumin 20% 15 ml/kg or no treatment (Lundstrom 2000) and found no significant difference in mortality (RR 0.92, 95% CI 0.23, 3.72) (Outcome 3.1) and no periventricular leucomalacia (Outcome 3.2) in either group.
Secondary outcomes: Infants receiving albumin had a trend to increased left ventricular output and cerebral blood flow, with little change in mean BP (see above). No other outcome data are available.
Primary outcomes: Four studies randomised infants to fresh frozen plasma or no treatment (Beverley 1985; Ekblad 1991; Gottuso 1976; NNNI 1996). Meta-analysis of three studies reporting mortality data (Beverley 1985; Gottuso 1976; NNNI 1996) involving a total of 654 infants found no significant difference in mortality (typical RR 1.05, 95% CI 0.81, 1.36) (Outcome 4.1). Two studies (Beverley 1985; Ekblad 1991) reported data on all infants randomised. Beverley 1985 found a significant reduction in P/IVH (RR 0.46, 95% CI 0.21, 0.98) whereas Ekblad 1991 found no significant difference (RR 1.21, 95% CI 0.31, 4.71). Meta-analysis of these 2 studies found a non-significant trend to reduced P/IVH in infants receiving volume (typical RR 0.58, 95% CI 0.30, 1.11; typical RD -0.14, 95% CI -0.29, 0.01) (Outcome 4.2). One study, Beverley 1985 found a non-significant trend to less P/IVH grade 3-4 (RR 0.55, 95% CI 0.21, 1.47), reduced death or P/IVH of borderline significance (RR 0.55, 95% CI 0.30, 1.03; RD -0.21, 95% CI -0.42, -0.01) and no significant difference in death or grade 3-4 P/IVH (RR 0.68, 95% CI 0.32, 1.46). From units with routine scan facilities, the NNNI 1996 study reported no difference in P/IVH in survivors examined (RR 1.20, 95% CI 0.83, 1.74), grade 2-4 P/IVH in survivors examined (RR 0.93, 95% CI 0.45, 1.95), death or P/IVH (RR 1.06, 95% CI 0.83, 1.37), death or grade 3-4 P/IVH (RR 1.01, 95% CI 0.72, 1.41) and periventricular leucomalacia in survivors (RR 0.76, 95% CI 0.40, 1.45). Rates of severe disability (RR 0.80, 95% CI 0.48, 1.34), death or severe disability (RR 0.94, 95% CI 0.73, 1.22) and cerebral palsy (RR 0.79, 95% CI 0.46, 1.34) were not significantly different.
Secondary outcomes: The NNNI 1996 study found no significant difference in the rate of treatment failure in infants born 1990-91 (hypotension: RR 0.71, 95% CI 0.27, 1.82). No data on the effect on blood flow were available. In the NNNI 1996 study, necrotising enterocolitis was significantly reduced (RR 0.22, 95% CI 0.06, 0.74) in infants receiving fresh frozen plasma, but sepsis significantly increased (RR 1.65, 95% CI 1.13, 2.40). Ekblad 1991 found an increase in PDA of borderline significance (RR 1.62, 95% CI 1.00, 2.62: RD 0.33, 95% CI 0.05, 0.61). Beverley 1985 found no difference in PDA (RR 1.14, 95% CI 0.53, 2.48). Meta-analysis of these two studies found no significant difference in PDA (typical RR 1.39, 95% CI 0.91, 2.14) (Outcome 4.12). No significant difference was found in the rates pneumothorax (Outcome 4.13). The NNNI 1996 study found no significant difference in the rate of renal impairment (data not given in paper) and Ekblad 1991 found no significant difference in creatinine clearance and urinary fractional sodium excretion in the first 5 days after birth.
One trial involving 20 infants in each group with a systolic BP < 40 mmHg compared fresh frozen plasma to albumin 4.5% 15 ml/kg (Emery 1992). No significant difference in change in mean BP was found. Both these groups had a significantly greater increase in mean BP than a control group who received albumin 20% 5 ml/kg. No difference in duration of ventilation was found. No other clinical data were available.
Primary outcomes: One study involving 519 infants compared a gelatin-based plasma substitute 20 ml/kg with no treatment (NNNI 1996). No significant differences were found in mortality (RR 1.22, 95% CI 0.86, 1.72). In a subgroup of infants from centres with routine scanning facilities there was no significant difference found in P/IVH in survivors (RR 0.89, 95% CI 0.58, 1.34), grade 2-4 P/IVH in survivors (RR 1.12, 95% CI 0.56, 2.27), death or P/IVH (RR 1.01, 95% CI 0.78, 1.30), death or grade 3-4 P/IVH (RR 1.23, 95% CI 0.90, 1.68) or periventricular leucomalacia in survivors (RR 0.62, 95% CI 0.31, 1.24). Rates of severe disability in all survivors (RR 0.79, 95% CI 0.47, 1.33), death or severe disability (RR 1.05, 95% CI 0.82, 1.34) and cerebral palsy in all survivors (RR 0.74, 95% CI 0.42, 1.28) were not significantly different.
Secondary outcomes: The NNNI 1996 study found no significant differences in the rate of treatment failure in a subgroup of infants born 1990-91 (hypotension: RR 0.40, 95% CI 0.13, 1.25), transient renal impairment, necrotising enterocolitis (RR 1.06, 95% CI 0.52, 2.15) and sepsis (RR 0.93, 95% CI 0.60, 1.44) . No data on the effect on blood flow, patent ductus arteriosus or retinopathy were available.
Primary outcomes: One study involving 519 infants compared a gelatin-based plasma substitute with fresh frozen plasma 20 ml/kg (NNNI 1996). No significant difference was found in mortality (RR 1.17, 95% CI 0.83, 1.64). In a subgroup of infants born in centres with routine scanning facilities, the rates of P/IVH in survivors (RR 0.74, 95% CI 0.49, 1.10), grade 2-4 P/IVH in survivors (RR 1.20, 95% CI 0.58, 2.50), death or P/IVH (RR 0.95, 95% CI 0.74, 1.21), death or grade 3-4 P/IVH (RR 1.22, 95% CI 0.89, 1.67) and periventricular leucomalacia in survivors (RR 0.81, 95% CI 0.38, 1.72) were similar. Rates of severe disability in all survivors (RR 0.99, 95% CI 0.57, 1.72), death or severe disability (RR 1.11, 95% CI 0.86, 1.43) and cerebral palsy in all survivors (RR 0.94 95% CI 0.52, 1.69) were not significantly different.
Secondary outcomes: The NNNI 1996 study found no significant difference in the rate of treatment failure in a subgroup of infants born 1990-91 (hypotension: RR 0.56, 95% CI 0.17, 1.90), or for transient renal impairment. The rate of necrotising enterocolitis was significantly higher (RR 4.92, 95% CI 1.44, 16.80) and sepsis significantly lower (RR 0.57, 95% CI 0.39, 0.83) in infants who received the gelatin based plasma substitute. No data on the effect on blood flow or rates of patent ductus arteriosus and retinopathy were available.
No randomised study was found that compared early red cell transfusion to control.
OTHER SUBGROUP ANALYSES:
1) According to timing of treatment (data not in MetaView tables):
Volume vs. no treatment: Early treatment (< 24 hours age): Four studies with gave volume expansion to infants within the first 24 hours after birth (Beverley 1985; Ekblad 1991; Gottuso 1976; NNNI 1996). Meta-analysis of three studies with data on mortality for 915 infants (Beverley 1985; Gottuso 1976; NNNI 1996) found no significant difference (typical RR 1.11, 95% CI 0.88, 1.41). All other outcomes are as for the comparison 'volume vs. no treatment'.
Colloid (5% albumin) vs. crystalloid (normal saline): Early treatment (< 24 hours): One study (So 1997) enrolled infants with hypotension at < 2 hours of age and reported no significant difference in mortality (RR 1.36, 95% CI 0.48, 3.82), any P/IVH (RR 1.52, 95% CI 0.68, 3.42) and grade 3 - 4 P/IVH (RR 1.61, 95% CI 0.42, 6.19). So 1997 reported no significant difference in treatment failure (RR 1.02, 95% CI 0.68, 1.55), rates of chronic lung disease (oxygen requirements at 28 days or 36 weeks postmenstrual age), patent ductus arteriosus, necrotising enterocolitis and sepsis. The other study (Lynch 2008) comparing albumin with normal saline enrolled hypotensive infants <3 days of age.
2) According to types of infants enrolled:
a) Unselected preterm infants (not selected on the basis of cardiovascular compromise): All studies that compared volume to no treatment enrolled infants on the basis of gestation or birthweight. See comparison of volume vs. no treatment.
b) Infants with clinical evidence of cardiovascular compromise: Three studies enrolled infants with clinical evidence of cardiovascular compromise. Emery 1992 enrolled hypotensive infants (systolic BP < 40 mmHg) to fresh frozen plasma 15 ml/kg or albumin 4.5% 15 ml/kg. A control group received albumin 20% 5 ml/kg. Lynch 2008 enrolled hypotensive preterm infants (mean BP < 5th percentile according to Vermsold criteria) to 5% albumin vs. normal saline 10ml/kg. So 1997 enrolled hypotensive infants with a low mean BP (defined by weight strata) to albumin 10 ml/kg or isotonic saline 10 ml/kg. Only one study (Lynch 2008) reported a significant difference with a significant reduction in treatment failure in infants receiving albumin (RR 0.54; 95% CI 0.30, 0.97) and a significant increase in mean BP (WMD 9.90 mmHg, 9% CI 1.22, 18.58) compared to normal saline. No differences were found for any outcomes (see comparisons of 'fresh frozen plasma versus albumin' and 'colloid versus crystalloid'). No studies were found that compared volume to no treatment in infants with cardiovascular compromise.
c) Infants with low blood flow: No studies were found that compared volume to no treatment in infants with low blood flow.
No statistically significant heterogeneity was found for any analysis included in this review. Comparing volume to no treatment: One small study (Beverley 1985) found a reduced rate of P/IVH. The other studies (Ekblad 1991; NNNI 1996) and the overall meta-analysis did not support a difference in P/IVH, high grade P/IVH or subsequent disability. Comparing albumin to normal saline: One study (Lynch 2008) reported a significant reduction in treatment failure and significantly greater increase in mean BP in hypotensive infants receiving albumin in the first 3 days. The other study (So 1997) reported no significant difference in treatment failure and no significant difference in % change in mean BP in infants enrolled <2 hours age.
The results of this review are not sensitive to excluding the study that did not state whether there was adequate allocation concealment (Ekblad 1991). Only one study stated that the interventions were blinded in any way (Lynch 2008) and this study compared 5% albumin with normal saline 10ml/kg in hypotensive infants in the first 3 days after birth. This study reported a significantly greater increase in mean BP in infants receiving albumin compared to normal saline (MD 9.9%, 95% CI 1.22, 18.58) but no significant difference in urine output (ml/kg/hr) for 6 hours after the 1st bolus (1.7 ± 2.2 vs. 1.8 ± 2) or cost of therapy per patient including pharmacy and nursing costs (albumin $US63.98 ± 8.03 vs. saline $US62.18 ± 8.58). Comparing volume with no treatment, one study with results for P/IVH had incomplete head ultrasound data at six weeks (NNNI 1996). Two studies had complete follow-up of infants for P/IVH (Beverley 1985; Ekblad 1991) and found a non-significant trend to reduced P/IVH (RR 0.6, 95% CI 0.3, 1.1; RD -0.14, 95% CI -0.29, 0.01) and grade 3 - 4 P/IVH (RR 0.6, 95% CI 0.2, 1.5; RD -0.11, 95% CI -0.27, 0.06) in infants receiving volume. No significant difference for combined death or P/IVH (RR 0.95, 95% CI 0.74, 1.21) was found. The NNNI 1996 study had complete follow-up for neurodevelopmental outcomes reporting no significant difference in severe disability (RR 0.80, 95% CI 0.52, 1.23), cerebral palsy (RR 0.76, 95% CI 0.48, 1.20) and death or severe disability (RR 1.00, 95% CI 0.80, 1.24).
Two studies were excluded from the analyses as insufficient volume (less than 10ml/kg) was given (Bland 1976; Greenough 1993) and the mean age of infants was > 32 weeks (Bland 1976). One study (Emery 1992) had data excluded from a subgroup of infants who received insufficient volume and did not meet the criteria for controls (given albumin 20% 5 ml/kg). These data do not meet inclusion criteria for this review. The excluded data from the study by Emery 1992 are given in 'results' in the comparison of 'fresh frozen plasma vs. albumin'. The inclusion of data from any of these comparisons has minimal impact on any of the estimates made in this review.
This review examines evidence from randomised controlled trials for the use of early volume expansion in very preterm infants. In subgroup analysis, it looks for evidence for the use of different types of volume expansion and for the use of volume expansion in different types of infants. The analysis had a power of 80% to detect a 9% absolute difference in rates of combined death and severe disability between volume and control groups at the 5% significance level. Six of the 7 trials reported adequate randomisation procedures and allocation concealment. Only one reported efforts to blind caregivers with this study comparing use of albumin with normal saline in hypotensive infants (Lynch 2008). Only one trial provided data on long-term neurodevelopment (NNNI 1996). This was the largest trial with no losses to follow-up and blinded assessment of neurodevelopment at two years, including the Griffiths' Scales of Mental Development and clinical examination. This trial had incomplete ascertainment of head ultrasound findings in a subgroup of infants born in centres with routine scan facilities. The studies with complete ascertainment of head ultrasound abnormalities are much smaller (Beverley 1985; Ekblad 1991).
The studies comparing volume to no treatment did not enrol infants with evidence of cardiovascular compromise. Infants were predominantly enrolled on the basis of gestation or birthweight. However, by virtue of their gestation or birthweight, these infants were at risk of mortality, P/IVH and disability. Whether or not these infants had hypovolaemia was not measured. The studies that did enrol infants on the basis of cardiovascular compromise enrolled infants on the basis of low BP and compared different forms of volume expansion. They did not have a control group that received no treatment. Blood flow (left ventricular output and cerebral blood flow) was measured by only one study (Lundstrom 2000). This study enrolled infants with stable cardiovascular status and normal mean BP who had not received volume or inotropes in the preceding three hours. There is no data on blood flow in infants with cardiovascular compromise.
There is no evidence to support the routine use of volume expansion given to very preterm infants on the basis of gestational age or birthweight in the first days after birth. There is no evidence that routine early volume expansion decreases the incidence of cardiovascular compromise (hypotension) or mortality. Evidence from one study of a reduced rate of P/IVH is not supported by the overall meta-analysis or any other study. No difference was seen in the rates of higher grade cerebral ischaemic lesions or subsequent disability. The observations from one study that infants who received fresh frozen plasma had a lower incidence of necrotising enterocolitis and higher incidence of sepsis should be treated with caution. The overall rate of mortality and disability were not different between infants who received fresh frozen plasma compared to no treatment in this study.
One study (Lynch 2008) reported a significant reduction in treatment failure (persistent hypotension) and a greater increase in mean BP in infants with hypotension treated with albumin compared to normal saline. Other clinical outcomes including mortality and P/IVH were not reported. The other study (So 1997) and the overall meta-analysis do not support a reduction in rate of treatment failure or change in mean BP, and there was no significant difference in mortality, P/IVH or other clinical outcomes. Differences between the studies identified in subgroup analyses included the different timing of intervention (Lynch 2008 enrolled infants < 3 days age and So 1997 enrolled infants < 2 hours age) and the lack of blinding of treatment in one study (So 1997). One study (NNNI 1996) reported no significant difference in mortality, P/IVH or disability in infants who received a gelatin-based plasma substitute compared to fresh frozen plasma. No data were available for the use of early blood transfusion. Data for the use of albumin compared to no treatment are only available from one small study with inadequate power to demonstrate any benefit and enrolling infants with a stable cardiovascular status.
There is no evidence from randomised trials to support the routine use of early volume expansion in preterm infants without evidence of cardiovascular compromise. There is insufficient evidence to determine whether infants with evidence of cardiovascular compromise benefit from volume expansion. There is insufficient evidence to determine what type of volume expansion should be used in preterm infants (if at all) and for the use of early red cell transfusions. The significance of the finding of a significant increase in BP in hypotensive preterm infants in one trial comparing colloid (albumin) and crystalloid (saline) is unclear, but the overall meta-analysis found no other clinical benefit in using albumin compared to saline.
The question of whether volume expansion should be given before or in addition to inotropes in preterm infants with cardiovascular compromise has not been answered. Future trials of volume expansion should identify and enrol those infants with low cardiac output or organ perfusion. Further trials of albumin vs. saline are warranted in infants with cardiovascular compromise. In addition to important clinical outcomes (mortality, cerebral ischaemic lesions and neurodevelopment) future trials should measure changes in cardiac output and/or organ blood flow. Further research is required into methods of detecting hypovolaemia in preterm infants.
DO wrote the review update. Both authors performed the updated literature search, assessed eligibility, critically appraised articles and performed data extraction independently.
Methods | Adequate randomisation: yes, sealed envelopes. |
---|---|
Participants | Infants <1500g or < 32 weeks. |
Interventions | Intervention (n = 38): fresh frozen plasma 10 ml/kg on admission and 24 hours of age. |
Outcomes | Stated primary outcome: P/IVH. |
Notes |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Methods | Adequate randomisation: method not stated. |
---|---|
Participants | Appropriate for gestational age preterm infants stratified by gestation: |
Interventions | Intervention (n = 21): Fresh frozen plasma 10 ml/kg over 2 hours, daily for 3 days, no additional sodium. |
Outcomes | Stated primary outcome: water balance and extracellular volume (bromide space), renal function. |
Notes | Data for grade of P/IVH in excluded infants requested from author. |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Unclear | B - Unclear |
Methods | Adequate randomisation: yes, sealed envelope. |
---|---|
Participants | Preterm infants day 1-4 (23-35 weeks, (552-1954g), hypotension with systolic BP < 40 mmHg. |
Interventions | Intervention: Group 1 (n = 20) fresh frozen plasma 15 ml/kg over 3 hours. |
Outcomes | Stated primary outcome: systolic BP one and 4 hours after infusions. |
Notes | No data available for inclusion in meta-analysis. |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Methods | Two centres. |
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Participants | Stratified into 3 groups: |
Interventions | Intervention: Supportive care and fresh frozen plasma 15 ml/kg (n = 26). |
Outcomes | Stated primary outcome: none stated. |
Notes | Infants randomised to exchange transfusion excluded from review. |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Methods | Adequate randomisation: yes, sealed envelopes. |
---|---|
Participants | Preterm infants < 33 weeks (median 28, range 25-32), arterial line, mean arterial BP 29 to 40 mmHg, normal blood glucose, no volume or inotrope support within preceding 3 hours. |
Interventions | Intervention (n = 13): albumin 20% 15 ml/kg. |
Outcomes | Stated primary outcome: mean arterial BP, left ventricular output, global cerebral blood flow. |
Notes | Data from publication used. Clinical data for mortality obtained from author. |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Methods | Single centre. |
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Participants | Infants admitted to NICU <24 hours age, ≦ 3 days age, mean arterial pressure <5th percentile by Versmold criteria for >10 minutes and parental permission. |
Interventions | 5% albumin 10ml/kg infused over 20 minutes (n = 49). |
Outcomes | Primary outcomes: improvement in arterial BP to normal (greater than the 10th percentile for mean BP for weight) at 1 hour after infusion. |
Notes |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Methods | Multicentre. |
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Participants | Infants < 32 weeks, < 2 hours old and clinician uncertain as to whether to use volume, no indications or contraindications to any of the interventions. |
Interventions | Intervention: Group 1 ( n = 257). Fresh frozen plasma 20 ml/kg over 15 mins, 10 ml/kg 24hrs later. |
Outcomes | Stated primary outcome: death before discharge or severe disability at 2 years. |
Notes | 77% of eligible infants enrolled. |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Methods | Adequate randomisation: yes, computer used. |
---|---|
Participants | Infants < 34 weeks, birthweight < 2000g, mechanically ventilated for RDS, hypotension (MAP < 25, 30, 35 mmHg at < 1kg, 1-1.49 kg, 1.5-1.99 kg respectively) at < 2 hours age, no previous fluids or inotropes. |
Interventions | Intervention (n = 32): 5% albumin 10 ml/kg over 30 mins up to 3 doses. |
Outcomes | Stated primary outcome: treatment failure (persistent hypotension requiring dopamine). |
Notes |
Item | Judgement | Description |
---|---|---|
Allocation concealment? | Yes | A - Adequate |
Reason for exclusion | Fresh frozen plasma versus no treatment. Printed in abstract form only. Volume of fresh frozen plasma not stated. No clinical data could be extracted for inclusion in review. |
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Reason for exclusion | No control group. |
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Reason for exclusion | Randomised trial of platelet transfusion in thrombocytopenic newborns. |
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Reason for exclusion | No control group. |
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Reason for exclusion | No control group. |
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Reason for exclusion | Randomised trial of two different volumes of packed red cell transfusions in haemodynamically stable very low birth weight infants. |
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Reason for exclusion | Retrospective cohort of 10 ml/kg 4.5% albumin infusion in 26 ventilated normotensive neonates with metabolic acidosis. |
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Reason for exclusion | Randomised trial of higher and lower fluid intakes. |
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Reason for exclusion | No control group. |
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Reason for exclusion | Insufficient volume to meet inclusion criteria. Mean age of infants > 32 weeks. Randomised preterm infants < 37 weeks with serum protein < 4.6 g% to receive glucose versus albumin 25% 8 ml/kg within 2 hours of birth. |
---|
Reason for exclusion | Randomized to red cell transfusion to maintain Hb > 10 g/L or control group. Intervention predominantly late. |
---|
Reason for exclusion | Randomised to albumin 1g/kg versus no treatment prior to exchange transfusion. |
---|
Reason for exclusion | Randomised trial of higher and low sodium intake. |
---|
Reason for exclusion | Used alternation to assign infants to exchange transfusion or control. |
---|
Reason for exclusion | No control group. Observed effect of albumin infusion on BP, pH and core-peripheral temperature difference. |
---|
Reason for exclusion | Randomised trial of 10ml/kg 4.5% albumin versus 4.2% sodium bicarbonate in acidotic newborn infants. Gestations not reported. Infants with hypotension or evidence of acute blood loss excluded. |
---|
Reason for exclusion | Randomised to high and low sodium intake. |
---|
Reason for exclusion | Given inadequate volume: 20% albumin 5 ml/kg given at maintenance fluid rate instead of maintenance fluids. Placebo was maintenance fluids. |
---|
Reason for exclusion | Randomised trial of 20% albumin 0.5g/kg in term newborns with perinatal asphyxia. |
---|
Reason for exclusion | Randomised trial of albumin infusion in term infants with non-haemolytic hyperbilirubinaemia. |
---|
Reason for exclusion | Randomised after 48-72 hours of age to addition of albumin to total parenteral nutrition. |
---|
Reason for exclusion | Trial of fluid restriction. |
---|
Reason for exclusion | No control group. |
---|
Reason for exclusion | No control group. |
---|
Reason for exclusion | Infants 3 to 16 days age. Infants randomly assigned to different infusion rates of maintenance fluids. |
---|
Reason for exclusion | Neonates 690–4030g, gestational age 26–40 weeks without cardiac or renal failure or major hemostasis abnormalities and requiring a peripherally inserted central catheter for parenteral nutrition. Median (1st/3rd quartiles) age enrolment HES group: day 3 (3, 6); saline: day 5 (4, 6). |
---|
Reason for exclusion | Hypotensive preterm infants (mean gestational age of 29 +/-3 week) randomly allocated to 10ml/kg 5% albumin versus isotonic saline versus hydroxyethyl starch (HES). Infants age at randomisation (days): albumin: 2+/-1; saline: 6 +/-10; HES: 5 +/- 6. |
---|
Reason for exclusion | Insufficient volume: used 3ml 25g/dl albumin injected per pound bodyweight 1–2 times weekly versus no albumin. Given after day 3. Treatment allocation by alternation with process not strictly adhered to. |
---|
Reason for exclusion | Randomised to packed red cell transfusion to maintain hematocrit > 0.35 or control. Mean time of transfusion 28 days |
---|
Reason for exclusion | Enrolled preterm infants with anaemia. Studied effect of blood transfusion. No control group. |
---|
Reason for exclusion | Infants < 4 days old excluded. Randomised study of 2 different infusion rates of red cell transfusion. |
---|
Reason for exclusion | Enrolled 50 newborn infants with hypotension in first 24 hours. Stratified randomisation of infants <2500g and >=2500. Excluded because of excessive post randomisation losses (9/39 =23%) for infants <2500g. |
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Reason for exclusion | Observational study of effects of sodium bicarbonate in acidotic infants. |
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Reason for exclusion | Comparison of 10 versus 20 ml/kg red blood cells in infants <1500g. Mean postnatal age 23-26 days. |
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Reason for exclusion | Enrolled infants aged 1–38 months, allocated randomly to 20 ml/kg HES 70/0.5 or Ringer's lactate during the first hour of urological surgery. |
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Reason for exclusion | No control group. |
---|
Reason for exclusion | No control group. |
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Reason for exclusion | Infants randomised to varying oxygen, alkali (rapid infusion of sodium bicarbonate) and ventilation strategies. |
---|
Reason for exclusion | No control group. |
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Reason for exclusion | Enrolled neonates undergoing major surgery. They were excluded if the body weight was less than 2kg. |
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Reason for exclusion | Enrolled infants with septic shock 1 month to 12 years age. |
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Reason for exclusion | Randomised to different volumes of maintenance fluids. |
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Reason for exclusion | Randomised infants with early onset sepsis to 10ml/kg intravenous immunoglobulin or albumin. |
---|
Reason for exclusion | Control group received bicarbonate. Crossover study of bicarbonate and albumin. Gestational ages of infants not stated. Printed in abstract form only. |
---|
Reason for exclusion | Infants <1500g with HCT <0.30 randomised to 2 different red cell transfusion volumes. |
---|
Reason for exclusion | Unable to obtain data from author. |
---|
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Summary Table of Comparisons and Outcomes
1 Volume vs. no treatment in very preterm infants
1.1 Death
1.2 Any P/IVH
1.2.1 Any P/IVH in infants randomised
1.2.2 Any P/IVH in survivors examined
1.3 Death or P/IVH
1.3.1 Death or P/IVH in infants randomised
1.3.2 Death or P/IVH in infants examined
1.4 P/IVH grade 2-4
1.4.1 P/IVH grade 2-4 in infants randomised
1.4.2 P/IVH grade 2-4 in survivors examined
1.5 P/IVH grade 3-4
1.6 Death or severe P/IVH
1.6.1 Death or P/IVH grade 3-4 in infants randomised
1.6.2 Death or P/IVH grade 3-4 in infants examined
1.7 Periventricular leucomalacia in survivors
1.7.1 PVL in all survivors
1.7.2 PVL in survivors examined
1.8 Severe neurodevelopmental disability in survivors
1.9 Death or severe neuodevelopmental disability
1.10 Cerebral palsy in survivors
1.11 Failed treatment (hypotension) in infants born 1990-1991
1.12 Patent ductus arteriosus
1.13 Pneumothorax
1.14 Necrotising enterocolitis
1.15 Sepsis
1.16 Change mean BP (%)
1.17 Change left ventricular output (%)
1.18 Change cerebral blood flow (%)
2 Colloid (albumin) vs. crystalloid (saline) in hypotensive infants
2.1 Death
2.2 Any P/IVH
2.3 P/IVH grade 3-4
2.4 Failed treatment
2.5 Chronic lung disease
2.5.1 Oxygen at 28 days
2.5.2 Oxygen or CPAP at 36-40 weeks
2.6 Patent ductus arteriosus
2.7 Necrotising enterocolitis
2.8 Sepsis
2.9 Change mean BP (%)
3 Albumin vs. no treatment in normotensive infants
3.1 Death
3.2 Periventricular leucomalacia in survivors
3.3 Change mean BP (%)
3.4 Change left ventricular output (%)
3.5 Change cerebral blood flow (%)
4 Fresh frozen plasma vs. no treatment in very preterm infants
4.1 Death
4.2 Any P/IVH
4.2.1 Any P/IVH in infants randomised
4.2.2 Any P/IVH in survivors examined
4.3 P/IVH grade 2-4
4.3.1 P/IVH grade 2-4 in infants randomised
4.3.2 P/IVH grade 2-4 in survivors examined
4.4 P/IVH grade 3-4
4.5 Death or P/IVH
4.5.1 Death or P/IVH in infants randomised
4.5.2 Death or P/IVHin infants examined
4.6 Death or P/IVH grade 3-4
4.6.1 Death or P/IVH grade 3-4 in infants randomised
4.6.2 Death or P/IVH grade 3-4 in infants examined
4.7 Periventricular leucomalacia in survivors examined
4.8 Severe neurodevelopmental disability in survivors
4.9 Death or severe neuodevelopmental disability
4.10 Cerebral palsy in survivors
4.11 Failed treatment (hypotension) in infants born 1990-1991
4.12 Patent ductus arteriosus
4.13 Pneumothorax
4.14 Necrotising enterocolitis
4.15 Sepsis
5 Gelatin vs. no treatment in very preterm infants
5.1 Death
5.2 Any P/IVH in survivors examined
5.3 P/IVH grade 2-4 in survivors examined
5.4 Death or P/IVH in infants examined
5.5 Death or P/IVH grade 3-4 in infants examined
5.6 Periventricular leucomalacia in survivors examined
5.7 Severe neurodevelopmental disability in survivors
5.8 Death or severe neuodevelopmental disability
5.9 Cerebral palsy in survivors
5.10 Failed treatment (hypotension) in infants born 1990-1991
5.11 Necrotising enterocolitis
5.12 Sepsis
6 Gelatin vs. fresh frozen plasma in very preterm infants
6.1 Death
6.2 Any P/IVH in survivors examined
6.3 P/IVH grade 2-4 in survivors examined
6.4 Death or P/IVH in infants examined
6.5 Death or P/IVH grade 3-4 in infants examined
6.6 Periventricular leucomalacia in survivors examined
6.7 Severe neurodevelopmental disability in survivors
6.8 Death or severe neuodevelopmental disability
6.9 Cerebral palsy in survivors
6.10 Failed treatment (hypotension) in infants born 1990-1991
6.11 Necrotising enterocolitis
6.12 Sepsis
This review is published as a Cochrane review in The Cochrane Library, Issue 1, 2009 (see http://www.thecochranelibrary.com for information). Cochrane reviews are regularly updated as new evidence emerges and in response to feedback. The Cochrane Library should be consulted for the most recent version of the review. |