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Trans R Soc Trop Med Hyg. Oct 2006; 100(10-4): 899–908.
PMCID: PMC2665701

Newborn resuscitation: defining best practice for low-income settings


Current resuscitation practices are often poor in low-income settings. The purpose of this review was to summarise recent evidence, relevant to developing countries, on best practice in the provision of newborn resuscitation. Potential studies for inclusion were identified using structured searches of MEDLINE via PubMed. Two reviewers independently evaluated retrieved studies for inclusion. The methodological quality of the selected articles was assessed using the Oxford Centre for Evidence-Based Medicine (CEBM) levels of evidence, whilst the Scottish Intercollegiate Guidelines Network (SIGN) grading system was used for subsequent recommendations. Based on available evidence, where there is meconium-stained liquor, routine perineal suction of all babies and endotracheal suction of active babies do not prevent meconium aspiration syndrome and have potential risks. Adequate ventilation is possible with a bag-valve-mask device and room air is just as efficient as oxygen for initial resuscitation. This review supports the view that effective resuscitation is possible with basic equipment and minimal skills. Thus, where resources are limited, it should be possible to improve neonatal outcomes through promotion of the effective use of a bag-valve-mask alone, without access to more sophisticated and expensive technologies. Basic, effective resuscitation should therefore be available at all health facilities and potentially in the community.

Keywords: Resuscitation, Best practice, Meconium aspiration syndrome, Meconium-stained amniotic fluid, Low-income settings

1. Introduction

Globally, over 5 million neonatal deaths occur each year. Birth asphyxia or failure to establish breathing at birth account for 19% of these deaths (Lawn et al., 2005a). In addition, birth asphyxia is closely associated with major neurodevelopmental sequelae such as cerebral palsy, cognitive impairment, epilepsy and chronic diseases later in life (Tan et al., 2004). Prematurity contributes another 28% to the total burden of newborn mortality (WHO, 2005), some due to inadequate respiratory support in the first minutes of life, whilst prematurity is also a risk factor for poorer outcomes in birth asphyxia (Costello and Manandhar, 1994). Perhaps less important, although still common, is the problem of meconium aspiration syndrome (MAS). Approximately 13% of liveborn infants are born through meconium-stained amniotic fluid (MSAF); of these, 5–12% develop MAS (Wiswell et al., 2000) manifesting as severe respiratory distress resulting in at best a requirement for careful, facility-based care and at worst death in 5–40% of cases (Fraser et al., 2005; Keenan, 2004; Wiswell et al., 1990). The implication of these statistics should be clear—that outcomes might be improved for more than 1 million infants per year through effective implementation of simple resuscitative techniques (Lawn et al., 2005a; Niermeyer et al., 2000).

However, whilst the fetal to neonatal transition during birth for all babies is marked by rapid and complex physiological changes critical to survival, most undergo a normal transition with only 5–10% requiring some degree of resuscitation at birth, ranging from simple stimulation to assisted ventilation (Tan et al., 2004). The problem for health workers and health systems is that it is often hard to predict reliably which pregnancies or labours will produce a baby requiring intervention. Reducing newborn mortality, whilst obviously depending on improved management of pregnancy and labour, therefore also requires that birth attendants should be able to provide basic newborn resuscitation (Bang et al., 2005). Such basic resuscitation, correctly done, is able to help most babies in need (WHO, 1997). However, even in health facilities, basic newborn resuscitation equipment may be missing, whilst health workers are often not adequately trained (English et al., 2004; WHO, 1997). The result is that observations of newborn resuscitation in developing countries often demonstrate poor practices (Kamenir, 1997). To a large extent, in many developing countries an inability to offer effective newborn resuscitation has been tolerated for many years. This largely reflects the belief that resuscitation is complex and dependent on the presence of (relatively) expensive technology making it ‘out of reach’ of low-income health systems.

However, emerging evidence suggests that resuscitation can and should be very simple without compromising the quality of the intervention (WHO, 1997). Following a simple A (airway), B (breathing) and C (circulation) approach it should be possible to provide resuscitation with simple equipment and minimal skills. The purpose of this review is to summarise the recent evidence, relevant to developing countries, that provides support for the view that effective newborn resuscitation can and should be provided in all health facilities and even perhaps in the community.

2. Methods

This review was aimed at answering the clinical questions on the ABC approach to newborn resuscitation included in Table 1. These questions emphasised topics that have major implications for the organisation and prioritisation of resuscitation services and the technology that supports resuscitation.

Table 1
Clinical questions

Potential studies for inclusion were identified by direct searches of the MEDLINE database via PubMed (1966–2005) by use of clinical queries (Haynes and Wilcynski, 2004; Montori et al., 2005). The following combinations of search terms were used:

Meconium aspiration: (meconium aspiration OR meconium OR meconium aspiration syndrome) AND (suction OR suctioning) AND newborn resuscitation;

Inflation breaths: resuscitation AND (inflation breaths OR breath*) AND (infant* OR neonat*);

Air vs. oxygen: (air OR oxygen) AND newborn resuscitation;

Chest compressions: resuscitation AND (compressions OR chest compression OR compression rates) AND (infant* OR neonat*);

Sodium bicarbonate: acidosis AND (sodium bicarbonate OR bicarbonate) AND (newborn OR infant OR neonat*);

Adrenaline: resuscitation AND (adrenaline OR epinephrine OR drugs) AND (newborn OR infant OR neonat*);

Glucose: resuscitation AND (glucose OR dextrose OR drugs) AND (newborn OR infant* OR neonat*).

The specific searches were aimed at identifying available evidence based on current randomised controlled trials (RCTs). However, where there were no RCTs, we briefly report findings based on previous literature reviews.

To ensure a comprehensive literature review, supplementary searches were conducted in the Cochrane Library, reference lists of all included articles and collections of experts in the field. The titles and abstracts of the retrieved articles were read by two independent reviewers and those that met the pre-set inclusion criteria were selected (see Appendix A).

The methodological quality of the selected articles was assessed using the Oxford Centre for Evidence-Based Medicine (CEBM) levels of evidence, which ranks the validity of evidence in a hierarchy of levels, with systematic reviews (SRs) as level 1 (strong evidence) and expert opinions as level 5 (weak evidence) (Phillips et al., 2001). Likewise, the grades of recommendations were based on the Scottish Intercollegiate Guidelines Network (SIGN) grading system, which places weight on the quality and body of evidence (Habour and Miller, 2001) (Appendix B).

2.1. Airway (A) (Table 2)

As soon as the umbilical cord is cut, if the baby is not already crying most authorities recommend that the baby is quickly dried with a (warm) towel for 10–15 s, re-wrapped in something clean and dry and placed where the baby can be kept warm. If the baby is now crying and active, an appropriate place is skin to skin on the mother's chest. If the baby is not crying after stimulation by effective drying or is not showing other signs of life, then resuscitation should begin. There is no place for more vigorous stimulation such as slapping the feet or bottom and as the baby is delivered no place for hanging the baby upside down to ‘drain out the liquor’.

2.1.1. Positioning

Failure to establish normal breathing at birth may result from the absence of a patent airway due to poor positioning of the head (or mechanical obstruction from blood, mucus or meconium). Thus, the first step for a baby should be to position the head in a neutral position to open the airway. The rationale and techniques for this are described in full elsewhere (Resuscitation Council (UK), 2000, 2001; WHO, 2006).

2.1.2. Nasal and oropharyngeal suction on the perineum to prevent MAS

At the present time, delivery room management of babies born through MSAF includes suctioning of the mouth and nose before delivery of the shoulders. This addresses the concern that babies will inhale meconium present in the upper airway with their first breath, putting them at risk of MAS. The rationale for routine perineal suctioning of all babies born through MSAF has recently been questioned.

In a large study (n = 2514) conducted in Argentina and the USA, the effectiveness of intrapartum oropharyngeal and nasopharyngeal suctioning of term infants being born through MSAF was assessed. It was concluded that the procedure does not prevent MAS (Vain et al., 2004): there was no significant difference between treatment groups in the incidence of MAS (52 (4%) suction vs. 47 (4%) no suction; relative risk (RR) 0.9, 95% CI 0.6–1.3), the need for mechanical ventilation for MAS (24 (2%) vs. 18 (1%); RR 0.8, 95% CI 0.4–1.4), mortality (9 (1%) vs. 4 (0.3%); RR 0.4, 95% CI 0.1–1.5) or the duration of ventilation, oxygen treatment and hospital care. On the contrary, the procedure has been shown to be potentially harmful; it may cause apnoea and cardiac arrhythmias triggered by pharyngeal stimulation, worsening hypoxia and delay the establishment of adequate tissue oxygen delivery as well as risking damage to the upper airway (Linder et al., 1988; Vain et al., 2004).

2.1.3. Endotracheal suction to prevent MAS

Tracheal suctioning of meconium in babies born through MSAF is an established intervention in many delivery rooms. However, recent evidence shows that this procedure might not be effective in reducing the incidence of MAS in active babies, i.e. those with good respiratory effort, heart rate >100 and reasonable tone.

Five studies have addressed the question of the efficacy of endotracheal suctioning of vigorous babies born through MSAF (Daga et al., 1994; Linder et al., 1988; Liu and Harrington, 1998; Wiswell et al., 2000; Yoder, 1994). Four studies (Daga et al., 1994; Linder et al., 1988; Liu and Harrington, 1998; Yoder, 1994), which compared vigorous term infants born through MSAF assigned to tracheal suction or routine care, showed no clear benefit of routine endotracheal suction. In subgroup analyses, this lack of benefit was apparent even in those born through very thick meconium (Yoder, 1994). On the contrary, the procedure was associated with an increase in minor pulmonary and laryngeal disorders (Linder et al., 1988). Similarly, in one large RCT (Wiswell et al., 2000), the incidence of MAS in the group assigned to tracheal suction was almost identical to the incidence in the group assigned to routine care without tracheal suction (3.2% vs. 2.7%, respectively). An additional Cochrane review that analysed four of the included studies (Daga et al., 1994; Linder et al., 1988; Liu and Harrington, 1998; Wiswell et al., 2000) came to similar conclusions (Halliday, 2000), although two of the studies (Daga et al., 1994; Liu and Harrington, 1998) had methodological flaws with randomisation and blinding of interventions.

2.2. Breathing (B) (Table 3)

2.2.1. Assisted ventilation: initial inflation breaths

After airway opening, if the baby is not breathing, is breathing irregularly or shallowly, or is blue, modern recommendations are to give the baby five slow chest inflations with a bag-valve-mask (BVM) device (Resuscitation Council (UK), 2001). The basis for these inflation breaths is that until birth the lungs are filled with fluid. To clear the lung fluid, sustained application of pressures of approximately 30 cm of water for 2–3 s is required in a term infant (lower pressures are recommended in preterm infants). Too low a pressure may be ineffective in achieving expansion of lungs with initially low compliance, whilst too high a pressure may result in lung damage, notably pneumothorax. These slow inflation breaths are also intended to maximise opening of the more peripheral airspaces (Resuscitation Council (UK), 2000, 2001). Recent evidence suggests that such pressures can be reliably achieved with a BVM device in competent hands, at least in simulations (O’Donnell et al., 2005).

Although supported by some experimental data and expert consensus, no RCTs were identified that have formally tested the value of inflation breaths when the baby fails to initiate breathing.

2.2.2. Assisted ventilation: air vs. oxygen

Traditionally, 100% oxygen has been used to resuscitate all asphyxiated newborns irrespective of the severity of their condition. This practice largely reflects the concern that the poor tissue oxygen delivery that is a routine part of the fetal to neonatal transition is exacerbated by problems at or during birth, resulting in systemic and damaging oxygen deficiency (Vento et al., 2003). Thus, the aim has always been to correct any oxygen debt rapidly in the expectation that this will prevent or ameliorate any damage. Whilst apparently logical, emerging evidence suggests that this intuitive approach, which appears to restrict the delivery of effective resuscitation to sites with access to oxygen, is of no benefit. Thus, six studies (Ramji et al., 1993, 2003; Saugstad et al., 1998, 2003; Vento et al., 2001, 2003), which compared resuscitation of asphyxiated newborns with room air or oxygen, found no differences between the groups with regard to mortality, morbidity and adverse neurodevelopmental outcomes. However, pooled analysis of an updated Cochrane review of four of the studies (Ramji et al., 1993, 2003; Saugstad et al., 1998; Vento et al., 2003) showed a significant reduction in the rate of death in the group resuscitated with room air (RR 0.71, 95% CI 0.54–0.94; risk difference (RD) −0.05, 95% CI −0.08 to −0.01); number needed to treat 20, 95% CI 12–100) (Tan et al., 2004). These findings suggest, contrary to common current practice, that one death would be prevented for every 20 babies resuscitated with air rather than 100% oxygen.

Interestingly, room air resuscitation (RAR) has also been shown to have a number of short-term benefits not observed with resuscitation using oxygen. Recovery among RAR infants is quick as assessed by Apgar scores, time to first breath and onset of a sustained pattern of respiration (Ramji et al., 2003; Saugstad et al., 1998; Vento et al., 2001, 2003). Conversely, use of 100% oxygen is associated with hyperoxia and alterations in cerebral circulation (Vento et al., 2003).

However, some questions remain. In five studies (Ramji et al., 1993, 2003; Saugstad et al., 2003; Vento et al., 2001, 2003), back-up oxygen was used for infants initially resuscitated with room air. However, this was allowed only for infants who remained cyanotic or bradycardic or in cases of resuscitation failure. Thus, there is a possibility that some subgroups of infants do require and benefit from resuscitation with oxygen. The effect on long-term development could also not be reliably determined because of methodological limitations in the one study that followed up infants beyond 12 months of age (Saugstad et al., 2003). Finally, the studies included few low birth weight/premature infants and thus the results cannot be extrapolated with confidence to this group. These topics should now be the subject of future specific trials that ideally improve on some of the methodological limitations encountered in the current data, including small numbers, inadequate long-term follow-up rates and lack of blinding of interventions/outcome measurements. Given these caveats, some caution should therefore be exercised in the application of the findings of the current studies to the whole population of babies requiring resuscitation.

2.3. Circulation (C)

As expected, there were no RCTs examining the value or delivery recommendations for chest compressions. Current guidelines are largely based on experimental animal data, simulation and expert consensus. The guidelines recommend compressions when bradycardia (heart rate <60/min and falling) persists despite adequate ventilation (Niermeyer et al., 2000; Resuscitation Council (UK), 2000). The compressions are required to deliver oxygenated blood primarily to the coronary circulation rather than the systemic circulation (in contrast to adult resuscitation, the heart is usually normal and just transiently ischaemic). Thus, compressions are only of value if one is certain that lung inflation has occurred (Resuscitation Council (UK), 2001). It is recommended that chest compressions should be co-ordinated with ventilations at a ratio of 3:1 to complete 30 cycles in 1 min, although the quality of chest expansion and compression is perhaps more important than attaining these rates.

2.4. Drugs (D) (Table 4)

Drugs have traditionally been used in newborns who do not respond to adequate ventilation and chest compressions (WHO, 1997). Clearly the emphasis is on adequate ventilation and compressions as drugs will be useless unless the primary problems of hypoxaemia/ischaemia are overcome and there is some degree of circulation (Resuscitation Council (UK), 2000, 2001). Although prominent in the minds of many, as well as evidence of their (inappropriate) prioritisation in practice in developing countries (Kamenir, 1997), there is little evidence for the value of drugs.

2.4.1. Sodium bicarbonate

Two small RCTs (Lokesh et al., 2004; Murki et al., 2004) that assessed the effects of sodium bicarbonate in asphyxiated neonates concluded that its administration does not help to improve survival or immediate neurological outcome. Similarly, a recent SR of base administration for preventing morbidity and mortality in preterm infants with metabolic acidosis found no statistically significant effect on mortality (RR 1.39, 95% CI 0.72–2.67; RD 0.12, 95% CI −0.12 to 0.36) or the incidence of intraventricular/periventricular haemorrhage (RR 1.24, 95% CI 0.47–3.28; RD 0.05, 95% CI −0.16 to 0.25) (Lawn et al., 2005b). The latter analysis reflected a concern that bicarbonate bolus may be associated with an increased incidence of intraventricular haemorrhage and hypernatraemia (Kamenir, 1997; Lawn et al., 2005b; Papile et al., 1978), although the volume/dose/concentration of sodium bicarbonate used may influence this outcome (Lokesh et al., 2004). The strength of the findings of this SR is, however, limited by the small number of studies (n = 2) and infants (n = 98) included. An additional review (Kecskes and Davis, 2002) found no evidence to support or refute the rapid correction of early metabolic acidaemia in low birth weight neonates.

These findings show that there is insufficient evidence to determine whether sodium bicarbonate infusion reduces morbidity and mortality or is even valuable in correcting acidosis in preterm infants with metabolic acidosis. Thus, further large randomised trials are needed.

2.4.2. Adrenaline

Adrenaline (through α-adrenergic-mediated vasoconstriction) theoretically elevates the perfusion pressure during chest compression hence enhancing delivery of oxygen to the heart and brain. It may also enhance the contractile state of the heart, stimulate spontaneous contractions and increase the heart rate (Niermeyer et al., 2000). Evidence for a valuable role in practice in human newborns is, however, lacking. One SR on adrenaline administration to apparently stillborn or extremely bradycardic newborn infants found no studies on mortality and morbidity outcomes. Similarly, no studies on optimum dosage and route of administration of adrenaline were found. The authors concluded that the current recommendations for adrenaline use in newborn infants are based solely on evidence from animal studies and human adults. Thus, studies are required to determine the role of adrenaline in neonates, including those of extremely low birth weight (Ziino et al., 2002).

The consensus view is that adrenaline administration can be considered if bradycardia persists after a minimum of 30 s of chest compressions and adequate ventilation as judged by good chest movement (Niermeyer et al., 2000; Resuscitation Council (UK), 2001). However, this is clearly only possible if there are at least two skilled personnel present.

2.4.3. Dextrose

There are no reported RCTs that have specifically examined the value of dextrose during newborn resuscitation. Therefore its role, if any, remains unestablished.

Expert consensus suggests that dextrose can be used if there is no response to adrenaline and sodium bicarbonate (Resuscitation Council (UK), 2001). The dextrose theoretically replenishes glycogen stores that are believed to diminish in the heart after delivery (Resuscitation Council (UK), 2001).

3. Implications for low-income settings

3.1. Environment/equipment

Newborn babies, especially small/asphyxiated babies, have difficulty in tolerating a cold environment. Continued exposure of the newborn to cold stress will result in a lower arterial oxygen tension and increased metabolic acidosis. To minimise evaporative heat loss, maintain a warm (25 °C) delivery room, keep all doors and windows closed, place the baby under a pre-heated radiant warmer for resuscitation if available and quickly dry the baby immediately after delivery (Niermeyer et al., 2000).

The minimum equipment needed for newborn resuscitation includes a dry towel, a bulb suction device and a bag and mask ventilator (Kamenir, 1997). A suggested list of resuscitation equipment is presented in Appendix C (Ministry of Health, 2002).

3.1.1. Recommendations

Based on the findings of this review, the following recommendations can be made with regard to practices pertinent to the ABC approach to newborn resuscitation in low-income settings. The grades of recommendations were based on the SIGN grading system (Appendix B).


To minimise evaporative heat loss, maintain a warm delivery room and dry the baby immediately after birth (Grade D).

A — Airway

Perineal suction is of no value and has potential risks. The practice should be stopped (Grade A).

Routine endotracheal suction of vigorous term babies born through MSAF is of no benefit and may be harmful even if there is thick meconium (Grade A).

Routine endotracheal suction in infants born through MSAF with poor tone/apnoea is of unknown value.

Airway suction should be in response to evidence of obstruction and should be done under direct vision — deep, blind suction should be avoided (Grade D).

If the baby is having difficulty in breathing, position the head in a neutral position to open the airway (Grade D).

B — Breathing

In cases of breathing difficulty, provide five inflation breaths each sustained for 2–3 s with a bag and mask ensuring that chest expansion is noted (Grade D).

Infants can be initially resuscitated with room air just as efficiently as with oxygen (Grade A); spare oxygen should continue to be made available where possible in case of resuscitation failure.

Application of the above A (airway) and B (breathing) steps that require a minimum of equipment should be promoted at peripheral health facilities and ideally at the community level where a large proportion of births occur. Effective resuscitation (by one person) can be supplied in approximately 95% of newborns requiring intervention by following these two straightforward steps.

C – Circulation

Chest compressions (after lung inflation) should be considered when bradycardia persists despite adequate ventilation (Grade D).

Co-ordinate chest compressions and ventilations; they should be in a ratio of 3:1 with approximately 90 compressions and 30 breaths per min (Grade D).

To improve the outcomes of high-risk deliveries at health facilities, skilled performance of chest compressions should be supported through newborn resuscitation training.

D — Drugs

The routine use of sodium bicarbonate to correct newborn metabolic acidosis does not help to improve survival or immediate neurological outcome. Bicarbonate infusion has potential risks. Thus, the practice should be stopped (Grade B).

Administration of adrenaline is of no proven benefit but may be indicated if bradycardia persists after a minimum of 30 s of chest compressions and adequate ventilation as judged by good chest movement (Grade D).

Dextrose is of no proven benefit but may be used if there is no response to adrenaline and sodium bicarbonate (Grade D).

It should be clear that there is little evidence for a useful role of drugs in newborn resuscitation. Therefore, their use should only be considered in delivery units with an adequate number of trained staff. Thus, only if adequate ventilation and chest compressions are being provided can drugs even be considered. Arguably, even if there are two resuscitators then the optimum approach would be for both to concentrate solely on the provision of effective approaches to A, B and C for at least 5 min, waiting for a third assistant before the use of drugs is considered.

3.1.2. Research gaps

Based on the findings of this review, the following emerged as priority areas for future research in developing countries.

There is need for future trials:

to establish whether community health workers or traditional birth attendants can be appropriately trained;

to investigate the role, if any, of routine endotracheal suctioning in neonates born through MSAF who are not vigorous at birth;

to determine the effects of room air or oxygen resuscitation on long-term neurodevelopmental outcomes in term and preterm infants;

to confirm the postulation that some subgroups of infants could benefit from resuscitation with oxygen supplementation. The basis for this is post hoc findings of the use of back-up oxygen in cases of resuscitation failures in the RAR group; and

to determine whether sodium bicarbonate infusion reduces morbidity and mortality in preterm infants with metabolic acidosis.

Conflicts of interest statement

The authors have no conflicts of interest concerning the work reported in this paper.


This work is published with the permission of the Director of KEMRI. Mike English is supported by a Wellcome Trust (UK) research fellowship (#050563). The advice of an informal WHO group collaborating to produce evidence summaries that inform guidelines for care of children in low-income settings is gratefully acknowledged.

Appendix A. Selection criteria for randomised controlled trials

Table thumbnail

Appendix B. Scottish Intercollegiate Guidelines Network (SIGN) grading system

Grades of recommendations

  • A
    At least one meta-analysis, systematic review (SR) or randomised controlled trial (RCT) rated as I++ and directly applicable to the target population; or a SR of RCTs or a body of evidence consisting principally of studies rated as I+ directly applicable to the target population and demonstrating overall consistency of results
  • B
    A body of evidence including studies rated as II++ directly applicable to the target population and demonstrating overall consistency of results; or extrapolated evidence from studies rated as I++ or I+
  • C
    A body of evidence including studies rated as II+ directly applicable to the target population and demonstrating overall consistency of results; or extrapolated evidence from studies rated as II++
  • D
    Evidence level III or IV; or extrapolated evidence from studies rated as II+

Levels of evidence

  • I++ High quality meta-analyses, systematic reviews (SRs) of randomised controlled trials (RCT), or RCTs with a very low risk of bias
  • I+ Well conducted meta-analyses, SRs of RCTs, or RCTs with a low risk of bias
  • I− Meta-analyses, SRs of RCTs, or RCTs with a high risk of bias
  • II++ High quality SRs of case–control or cohort studies. High quality case–control or cohort studies with a very low risk of confounding, bias, or chance and a high probability that the relationship is causal
  • II+ Well conducted case–control or cohort studies with a low risk of confounding, bias, or chance and a moderate probability that the relationship is causal
  • II− Case–control or cohort studies with a high risk of confounding, bias, or chance and a significant risk that the relationship is not causal
  • III Non-analytical studies, e.g. case reports, case series
  • IV Expert opinion

Appendix C. Recommended equipment for resuscitation of the newborn


Source of heat, e.g. heater or lamp or Resuscitaire®

Ambu bag (infant size)

Warm dry linen

Face masks sizes 0 and 1, preferably round

A pair of scissors, strapping and tapes


Source of oxygen, flow meter and tubings

Suction equipment, i.e. rigid, large bore (Yankauer) suction tube and catheters, sizes F6, 8, 10

Syringes and needles/swabs, preferably 1 ml, 2 ml, 10 ml


Specialist use

Laryngoscope with extra batteries and bulb

Laryngoscope blades sizes 0 and 1, preferably straight blade

Endotracheal tube size 2.5 mm, 3.0 mm, 3.5 mm

Umbilical catheters

Nasogastric tube size F4 can be used as umbilical catheter

Airway sizes: 000, 00, 0


10% dextrose


Bang A.T., Bang R.A., Baitule S.B., Reddy H.M., Deshmukh M.D. Management of birth asphyxia in home deliveries in rural Gadchiroli: the effect of two types of birth attendants and of resuscitating with mouth-to-mouth, tube-mask or bag-mask. J. Perinatol. 2005;25(Suppl. 1):S82–S91. [PubMed]
Costello A.M.L., Manandhar D.S. Perinatal asphyxia in less developed countries. Arch. Dis. Child. Fetal Neonatal Ed. 1994;71:F1–F3. [PMC free article] [PubMed]
Daga S.R., Dave K., Mehta V., Pai V. Tracheal suction in meconium stained infants: a randomized controlled study. J. Trop. Pediatr. 1994;40:198–200. [PubMed]
English M., Esamai F., Wasunna A., Were F., Ogutu B., Wamae A., Snow R.W., Peshu N. Delivery of paediatric care at the first-referral level in Kenya. Lancet. 2004;364:1622–1629. [PubMed]
Fraser W.D., Hofmeyr J., Lede R., Faron G., Alexander S., Goffinet F., Ohlsson A., Goulet C., Turcot-Lemay L., Prendiville W., Marcoux S., Laperriere L., Roy C., Petrou S., Xu H.R., Wei B. Amnioinfusion for the prevention of the meconium aspiration syndrome. N. Engl. J. Med. 2005;353:909–917. [PubMed]
Habour R., Miller J. A new system for grading recommendations in evidence based guidelines. BMJ. 2001;323:334–336. [PMC free article] [PubMed]
Halliday, H.L., 2000. Endotracheal intubation at birth for preventing morbidity and mortality in vigorous, meconium-stained infants born at term. Cochrane Database Syst. Rev. (2):CD000500. [PubMed]
Haynes R.B., Wilcynski N.L. Optimal search strategies for retrieving scientifically strong studies of diagnosis from Medline: analytical survey. BMJ. 2004;328:1040. [PMC free article] [PubMed]
Kamenir S.A. Neonatal resuscitation and newborn outcomes in rural Kenya. J. Trop. Pediatr. 1997;43:170–173. [PubMed]
Kecskes, Z.B., Davis, M.W., 2002. Rapid correction of early metabolic acidaemia in comparison with placebo, no intervention or slow correction in LBW infants. Cochrane Database Syst. Rev. (1):CD002976. [PubMed]
Keenan W.J. Recommendations for management of the child born through meconium-stained amniotic fluid. Pediatrics. 2004;113:133–134. [PubMed]
Lawn J.E., Cousens S., Zupan J., Lancet Neonatal Survival Steering Team 4 million neonatal deaths: when? where? why? Lancet. 2005;365:891–900. [PubMed]
Lawn, C.J., Weir, F.J., McGuire, W., 2005b. Base administration or fluid bolus for preventing morbidity and mortality in preterm infants with metabolic acidosis. Cochrane Database Syst. Rev. (2):CD003215. [PubMed]
Linder N., Aranda J.V., Tsur M., Matoth I., Yatsiv I., Mandelberg H., Rottem M., Feigenbaum D., Ezra Y., Tamir I. Need for endotracheal intubation and suction in meconium-stained neonates. J. Pediatr. 1988;112:613–615. [PubMed]
Liu W.F., Harrington T. The need for delivery room intubation of thin meconium in the low-risk newborn: a clinical trial. Am. J. Perinatol. 1998;5:675–682. [PubMed]
Lokesh L., Kumar P., Murki S., Narang A. A randomized controlled trial of sodium bicarbonate in neonatal resuscitation—effect on immediate outcome. Resuscitation. 2004;60:219–223. [PubMed]
Ministry of Health, 2002. National guidelines for quality obstetrics and perinatal care.Ministry of Health, Division of Reproductive Health, Kenya.
Montori V.M., Wilcynski N.L., Morgan D., Haynes R.B. Optimal search strategies for retrieving systematic reviews from Medline: analytical survey. BMJ. 2005;330:68. [PMC free article] [PubMed]
Murki S., Kumar P., Lingappa L., Narang A. Effect of a single dose of sodium bicarbonate given during neonatal resuscitation at birth on the acid–base status on first day of life. J. Perinatol. 2004;24:696–699. [PubMed]
Niermeyer S., Kattwinkel J., van Reempts P., Nadkarni V., Phillips B., Zideman D., Azzopardi D., Berg R., Boyle D., Boyle R., Burchfield D., Carlo W., Chameides L., Denson S., Fallat M., Gerardi M., Gunn A., Hazinski M.F., Keenan W., Knaebel S., Milner A., Perlman J., Saugstad O.D., Schleien C., Solimano A., Speer M., Toce S., Wiswell T., Zaritsky A. International Guidelines for Neonatal Resuscitation: an excerpt from the Guidelines 2000 for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care: International Consensus on Science. Contributors and Reviewers for the Neonatal Resuscitation Guidelines. Pediatrics. 2000;106:E29. [PubMed]
O’Donnell C.P.F., Davis P.G., Lau R., Dargaville P.A., Doyle L.W., Morley C.J. Neonatal resuscitation 2: an evaluation of manual ventilation devices and face masks. Arch. Dis. Child. Fetal Neonatal Ed. 2005;90:F392–F396. [PMC free article] [PubMed]
Papile L.A., Burstein J., Burstein R., Koffler H., Koops B. Relationship of intravenous sodium bicarbonate infusions and cerebral intraventricular hemorrhage. J. Pediatr. 1978;93:834–836. [PubMed]
Phillips, B., Ball, C., Sackett, D., Badenoch, D., Straus, S., Haynes, B., Dawes, M., 2001. Centre for Evidence-Based Medicine levels of evidence and grades of recommendation (May 2001). http://www.cebm.net/levels_of_evidence.asp#top[accessed 8 December 2005].
Ramji S., Ahuja S., Thirupuram S., Rootwelt T., Rooth G., Saugstad O.D. Resuscitation of asphyxic newborn infants with room air or 100% oxygen. Pediatr. Res. 1993;34:809–812. [PubMed]
Ramji S., Rasaily R., Mishra P.K., Narang A., Jayam S., Kapoor A.N., Kambo I., Mathur A., Saxena B.N. Resuscitation of asphyxiated newborns with room air or 100% oxygen at birth: a multicentric clinical trial. Indian Pediatr. 2003;40:510–517. [PubMed]
Resuscitation Council (UK) Resuscitation Council (UK); London: 2000. Newborn life support. Resuscitation guidelines.
Resuscitation Council (UK) Resuscitation Council (UK); London: 2001. Newborn life support provider course manual.
Saugstad O.D., Rootwelt T., Aalen O. Resuscitation of asphyxiated newborn infants with room air or oxygen: an international controlled trial: the Resair 2 study. Pediatrics. 1998;102:E1. [PubMed]
Saugstad O.D., Ramji S., Irani S.F., El-Meneza S., Hernandez E.A., Vento M., Talvik T., Solberg R., Rootwelt T., Aalen O.O. Resuscitation of newborn infants with 21% or 100% oxygen: follow-up at 18 to 24 months. Pediatrics. 2003;112:296–300. [PubMed]
Tan, A., Schulze, A., O’Donnell, C.P.F., Davis, P.G., 2004. Air versus oxygen for resuscitation of infants at birth. Cochrane Database Syst. Rev. (3):CD002273. [PubMed]
Vain N.E., Szyld E.G., Prudent L.M., Wiswell T.E., Aguilar A.M., Vivas N. Oropharyngeal and nasopharyngeal suctioning of meconium-stained neonates before delivery of their shoulders: multicentre, randomised controlled trial. Lancet. 2004;364:597–602. [PubMed]
Vento M., Asensi M., Sastre J., Garcýa-Sala F., Pallardo F.V., Vina J. Resuscitation with room air instead of 100% oxygen prevents oxidative stress in moderately asphyxiated term neonates. Pediatrics. 2001;107:642–647. [PubMed]
Vento M., Asensi M., Sastre J., Lloret A., Garcia-Sala F., Vina J. Oxidative stress in asphyxiated term infants resuscitated with 100% oxygen. J. Pediatr. 2003;142:240–246. [PubMed]
WHO, 1997. Basic newborn resuscitation: a practical guide. World Health Organization, Geneva.
WHO, 2005. The world health report 2005: make every mother and child count.World Health Organization, Geneva.
WHO, 2006. Guidelines for the management of common illnesses with limited resources. World Health Organization, Geneva.
Wiswell T.E., Tuggle J.M., Turner B.S. Meconium aspiration syndrome: have we made a difference? Pediatrics. 1990;85:715–721. [PubMed]
Wiswell T.E., Gannon C.M., Jacob J., Goldsmith L., Szyld E., Weiss K., Schutzman D., Cleary G.M., Filipov P., Kurlat I., Caballero C.L., Abassi S., Sprague D., Oltorf C., Padula M. Delivery room management of the apparently vigorous meconium-stained neonate: results of the multicenter, international collaborative trial. Pediatrics. 2000;105:1–7. [PubMed]
Yoder B.A. Meconium-stained amniotic fluid and respiratory complications: impact of selective tracheal suction. Obstet. Gynecol. 1994;83:77–84. [PubMed]
Ziino, A.J., Davies, M.W., Davis, P.G., 2002. Epinephrine for the resuscitation of apparently stillborn or extremely bradycardic newborn infants. Cochrane Database Syst. Rev. (2):CD003849. [PubMed]


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