In Spain, TH began to be used in 2008; in 2011, the Spanish Society of Neonatology published a series of guidelines standardising the application of hypothermia10. In 2014, a group of experts drafted clinical practice guidelines for the Spanish Ministry of Health, Social Services, and Equality based on the available evidence on the management of neonates with HIE11. TH was quickly implemented in Spanish hospitals, with 57 of the 90 public tertiary hospitals (60%) offering this treatment in 2015; over 85% of neonates with moderate/severe HIE received this treatment, although resource centralisation and optimisation remain a problem12.

Although TH is the main successful treatment for HIE and its usefulness in neuroprotection has been confirmed, this strategy only reduces the absolute risk of death or severe disability by approximately 15% as compared to not receiving TH (61% vs 46%)9,13.

To improve the neuroprotective efficacy of TH, several factors must be controlled; these include comorbid factors, time of onset, duration and depth of hypothermia, rewarming, sedoanalgesia, and concomitant treatments.

In clinical practice, the effectiveness of TH seems to be greater than reported in the early RCTs14. Among the factors contributing to this difference are those occurring in the first hours of life: adequate resuscitation in the delivery room, early administration of TH with passive cooling following stabilisation of the neonate, and comprehensive control of comorbid factors that may aggravate hypoxic-ischaemic injury before and during TH (eg, hyperthermia, hypoglycaemia, hypo- or hypercarbia, hypo- or hyperoxia, hypocalcaemia, and hypomagnesaemia in the first hours). Strategies aimed at controlling these factors are known as the “brain neuroprotection chain” and constitute a fundamental pillar in optimising neuroprotection during the first hours of life15.

Neurological examination enables rapid screening of neonates with HIE. Determining the severity of HIE within 6 hours after birth is a key element in the brain neuroprotection chain; severity is determined with clinical scales15. Most scales are nominal, establishing 3 degrees of severity: mild, moderate, or severe16–19. One difficulty of determining HIE severity lies in the fact that most scales do not provide a working definition for their items. However, accurately establishing the severity of HIE is essential to indicating TH and drawing robust conclusions in observational studies and RCTs.

In preclinical studies, TH has been found to confer greater neuroprotection when started immediately after hypoxic-ischaemic injury, and within the first 6 hours of life20. However, the therapeutic window may narrow according to the severity of hypoxic-ischaemic injury21.

Clinical data have shown a correlation between the time of TH onset and outcomes: the treatment should ideally be started within the first 3 hours of life22,23. This suggests that an effective way to improve the outcomes of TH is to diagnose and determine the severity of HIE as quickly as possible, with a view to starting treatment early.

HIE is therefore a time-dependent emergency in terms of both diagnosis and treatment. In many cases, TH must be started in the referring hospital prior to the patient’s arrival at the reference centre, which means that a stable temperature must be maintained during transfer24. Ten years after the introduction of TH programmes for neonates with HIE in our setting, cooling during transfer continues to be exclusively passive, as no servo-controlled cooling equipment is available24,25. In addition to this, no standardised guidelines have been issued on the management of these patients during transfers, and healthcare teams are rarely trained for this scenario15.

A duration of 72 hours and a cooling depth of 33-34°C have been established, based exclusively on the results of preclinical studies26. However, this approach has been found to be adequate, since experimental and clinical studies using longer and deeper cooling have not obtained better outcomes but do report higher systemic morbidity rates27–29. In preclinical studies, shorter durations (48 hours) have been associated with progressive deterioration over the rewarming phase, with histological findings suggesting reactivation of the inflammatory process associated with injury and rewarming30.

Rewarming is a critical stage, and must be slow (0.2-0.5°C/h)10. This strategy was used in the first RCTs due to concern that rapid rewarming may lead to cardiovascular instability and uncoupling of brain oxygen supply and consumption. In animals and adult humans, rapid rewarming is associated with poorer prognosis, whereas slow rewarming preserves the benefits of cooling31,32.

Rewarming occasionally triggers seizures, which may be subclinical, underscoring the need for continuous monitoring of brain electrical activity during this stage. When this occurs, rewarming should be slowed or even temporarily suspended. TH may reduce such proinflammatory responses as the release of complement and cell adhesion molecules, as well as oxidative stress and the release of excitotoxic amino acids; these processes may be reactivated during rewarming. Furthermore, increases in body temperature increase brain energy metabolism and, consequently, oxygen and glucose consumption.

Although little information is available, the evidence described above suggests that rewarming is a critical phase for neuroprotection; it has been suggested that slower rewarming following TH may result in greater neuroprotection32.

Although it is unclear whether sedoanalgesia, which aims to minimise pain or stress responses during TH, increases the efficacy of the procedure, the practice is used based on the observation that stress and/or pain seem to counteract the neuroprotective benefits of TH in preclinical models33.

In a retrospective study of neonates with HIE, patients treated with opioids presented less severe brain damage on MRI and better long-term neurological outcomes34. A European multicentre RCT evaluating the efficacy of TH revealed greater efficacy than that reported in previous clinical trials (number needed to treat of 4, vs 6-9); this improvement was attributed to the fact that neonates receiving TH had been sedated35.

Unsolved questions include the suitability and dosage of the drug, and the clinical scales and neurophysiological tools used to assess distress. Dexmedetomidine is an attractive alternative to opioids as it is less detrimental to respiratory function and intestinal motility, and has potential neuroprotective effects; however, it may also play a role in cardiovascular instability36,37.

Pending further evidence, we recommend systematic sedation of neonates undergoing TH, above all due to the ethical imperative to minimise the discomfort and stress associated with the procedure.

To guarantee the efficacy and safety of TH, the RCTs conducted to date establish age > 6 hours as an exclusion criterion7. This cut-off point is mainly based on experimental research, with secondary cerebral energy failure, beginning 5.5-8 hours after injury, marking the end of the therapeutic window20. Both in animal models and in humans, the neuroprotective effects of hypothermia after a hypoxic-ischaemic event seem to decrease over time20,23.

Treatment onset may be delayed due to several factors, including difficulty determining HIE severity in the first hours, patient transfer to a tertiary centre, lack of availability of cooling equipment, or severe patient instability in the first hours1. However, a recent well-designed study showed that onset of TH between 6 and 12 hours after birth has neuroprotective effects in neonates with moderate HIE (but not in those with severe HIE)38. Another study found that TH starting 6 to 24 hours after birth may have some therapeutic benefit39. Although the benefits are more modest than when TH is started within 6 hours after birth, these data support the use of TH beyond the 6-hour mark in neonates with moderate HIE.

RCTs on the efficacy of TH for HIE did not include neonates with mild HIE, as the available evidence at the time suggested that these patients do not present relevant neurodevelopmental alterations16,40–42. In the era of TH, 2 RCTs that incidentally included a small number of neonates with mild HIE reported no neurodevelopmental alterations as compared to the control group43,44.

However, 3 recent prospective studies have indicated that neonates with mild HIE are at considerable risk of presenting neurodevelopmental alterations45–47. A systematic review found that 25% of neonates with mild HIE presented unfavourable outcomes, defined as death or severe disability (cerebral palsy, blindness, or sensorineural deafness), developmental delay, or cognitive impairment48. However, the working definition of mild HIE was not homogeneous.

A recent multicentre, prospective study including 63 neonates and using a clear, uniform working definition of mild HIE found that 7 of 43 patients presented disability at the age of 18-22 months46. Only one of these 7 patients presented cerebral palsy, and the most frequent alteration was scoring < 85 on the Bayley-III Cognitive Scale. These data are consistent with the results of 2 studies reporting lower cognitive scale scores (mean difference of 6 points) in children with mild HIE than in patients with history of perinatal asphyxia but not presenting HIE, both at ages 2 and 5 years45,47. It is unclear whether clinical data or biomarkers may help us to identify the subgroup of neonates with mild HIE who will subsequently develop neurodevelopmental alterations, particularly cognitive scale scores < 85. This question should be addressed in future studies.

In conclusion, it is unclear whether the benefits of TH in neonates with mild HIE outweigh the costs. This treatment is associated with a number of difficulties and complications, as it requires transfer of the patient to a tertiary centre, involves the administration of sedatives and respiratory support, and results in considerable family distress and healthcare costs49. As mentioned previously, the HIE assessment tools currently available do not accurately reflect the continuous spectrum of clinical severity; as a result, differentiating between mild and moderate HIE is difficult in some cases. Although it is currently accepted that TH should not be indicated for neonates with clearly mild HIE, it should be administered when it is unclear whether HIE is mild or moderate.

The first RCTs applied strict inclusion criteria in order to gather robust evidence and to avoid confounding factors. In clinical practice, however, up to 22% of neonates undergoing TH do not meet these criteria50. TH has been applied to neonates with HIE associated with such other conditions as: 1) congenital heart disease, 2) need for surgery, 3) intra- or extracranial bleeding, 4) ischaemic stroke, 5) encephalopathy following postnatal collapse, and 6) late preterm infants (32-36 weeks of gestational age)50–52. In these situations, TH is used as a compassionate treatment and should be carefully evaluated on a case-by-case basis after ruling out pre-existing conditions that may be exacerbated by TH; the limitations of the available evidence should always be discussed with patients’ families52.

However, not all these potential indications for TH are equally accepted. While TH is more widely accepted in patients with encephalopathy following postnatal collapse51,53, its use in the context of HIE and extracranial (subgaleal haematoma) or intracranial haemorrhage is more controversial: the limited data available suggest that these patients present a high risk of complications, as TH may worsen the bleeding. Therefore, this treatment should not be started until haemorrhage and coagulation are under control, and only mild hypothermia should be applied (rectal temperature of 35°C, rather than 33°C)54.

Furthermore, indication of TH is controversial in premature infants younger than 36 weeks, as the treatment may cause more severe adverse events in these patients than in full-term infants, including coagulation disorders, immunosuppression, a leftward shift of the oxygen-haemoglobin dissociation curve, and alterations in the pharmacokinetic properties of drugs metabolised by the liver. These effects suggest an increased risk of intracranial haemorrhage, nosocomial infections, and poor oxygenation in these patients.

Although preclinical data from preterm animal models suggest that TH has neuroprotective effects55, 2 observational studies addressing the safety profile of this therapy do not report promising results56,57. A study including 31 preterm infants (34-35 weeks of gestational age) and 32 full-term infants revealed that preterm infants undergoing TH presented more complications associated with the procedure (hyperglycaemia, leukopaenia, and a trend toward greater frequency of coagulopathy). They also presented more frequent and more severe brain lesions, particularly white matter alterations and cerebellar lesions. Lastly, 13% of premature infants died, whereas no deaths were recorded in the full-term birth group57. The second study included 30 premature infants (33-35 weeks of gestational age); although it did not include a control group of full-term infants, it reports a prevalence of hypothermia-related complications (77%) similar to that of the previous study, with 75% of infants presenting neuroimaging alterations (which were moderate or severe in 35% of the sample) and 50% dying or presenting neurological disability56.

These discouraging findings may be explained by greater vulnerability to hypoxic-ischaemic injury in this population, but underscore the need to conduct further RCTs before TH can be indicated for preterm neonates. However, as this treatment has been shown to be safe for neonates with HIE born at 34-35 weeks of gestational age50, we support its indication on an individual basis for neonates of that gestational age, but not for those born before week 34.

On the other hand, asphyxiated neonates with clinical signs of HIE who present respiratory failure and severe pulmonary hypertension (eg, meconium aspiration syndrome) and require extracorporeal membrane oxygenation (ECMO) have traditionally been excluded from TH protocols due to the high risk of haemorrhagic complications. Although some small series suggest that applying hypothermia in conjunction with ECMO is feasible and does not increase the risk of complications58, an analysis of prospective data from 8 hospitals from the Collaborative Pediatric Critical Care Research Network revealed increased rates of intracranial haemorrhage in neonates receiving TH and recommended that this neuroprotective technique be used with caution in neonates with HIE who require ECMO59.

Given the wide range of reasons why neonates with HIE may not meet the classic inclusion criteria, and the small number of patients with other conditions, it is challenging to conduct RCTs with sufficiently large samples and to determine the safety and effectiveness of this therapeutic strategy in these contexts. However, as the use of TH in contexts other than the condition for which it was originally conceived must be thoroughly documented, the difficulties mentioned above may be surpassed by conducting proof-of-concept studies using reliable biomarkers of ischaemic damage with high predictive capacity, such as magnetic resonance spectroscopy (lactate–to–N-acetyl aspartate ratio) or biochemical markers51,60. This strategy may yield efficacy data faster and using fewer patients, which would be particularly beneficial in this context.

Healthcare professionals involved in the management of neonates with HIE are faced with the challenge of establishing a prognosis and informing patients’ families. Over the last decade, significant prognostic information has been obtained for each of the tests used to estimate the likelihood of long-term disability or death61. However, informing families remains one of the most difficult aspects in the management of these patients. Establishing a prognosis in such a narrow time window is another source of stress for the physicians attending these patients. This time window is vitally important in determining each patient’s needs and the onset of palliative care in the most severe cases. Delays in therapeutic decision-making may result in severe disability and dependence in cases of severe brain damage. These decisions should be based on high standards, ethical responsibility, and coherence, and based on a thorough analysis of prognostic data and the values of the patient’s family62. Healthcare professionals in our setting perceive and acknowledge this complexity. In our study, conducted in Spain, only half of tertiary centres had adequate resources for proper communication, and many reported difficulties developing interdisciplinary collaboration including nursing staff1,63. This constitutes a key challenge for improving teamwork when administering TH and establishing a therapeutic relationship with families to help them face this difficult situation.

Given the poor outcomes in nearly half of neonates undergoing TH, the development of new coadjuvant therapies to improve the neurodevelopmental outcomes of these infants is a top priority. Several therapies with endogenous products (erythropoietin, melatonin, cannabidiol, stem cells) are currently under study64. Other studies are focusing on such exogenous products as xenon, allopurinol, and topiramate; however, insufficient evidence is currently available to support their use in clinical practice64,65. In any case, we hope that some of these therapies will eventually be incorporated into clinical practice, extending the therapeutic window of TH and providing additional protection, which would ultimately decrease the rates of neurological disability associated with HIE.