The Journal of physiology
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The Journal of physiology · Jan 2020
Active cooling temperature required to achieve therapeutic hypothermia correlates with short-term outcome in neonatal hypoxic-ischaemic encephalopathy.
Hypoxic-ischaemic encephalopathy (HIE) affects 2-4/1000 live term births. Treatment with therapeutic hypothermia (TH) improves the long-term neurodevelopmental outcome of neonates with moderate to severe HIE. However, early prediction of outcome still remains challenging, and no reliable and easily obtainable biomarker has been identified to date. Neonates with HIE display impaired thermoregulation, resulting in spontaneous hypothermia. The degree of cooling required to achieve TH may therefore act as a biomarker of injury severity. The present study demonstrates a correlation between servo-controlled mattress temperature during TH and short-term outcome. Neonates with an unfavourable outcome require less cooling to maintain a core temperature between 33 and 34°C during TH compared to neonates with a favourable outcome. The degree of impaired temperature regulation was strongly associated with a high magnetic resonance imaging injury score and death. Cooling device output temperature is a potential and easily obtainable early physiological biomarker of outcome in infants with HIE undergoing TH. ⋯ Neonatal hypoxic-ischaemic encephalopathy (HIE) is a leading cause of death and disability in children. Therapeutic hypothermia (TH) at 33.5°C for 72 h is the only therapy to date shown to improve outcome in moderate to severe HIE; however, assessment of severity and prediction of outcome remains challenging. Infants with HIE display significant physiological perturbations, including spontaneous hypothermia. We hypothesized that neonates with more severe brain injury on magnetic resonance imaging (MRI) would exhibit a greater degree of spontaneous hypothermia, and thus require less active cooling to attain TH. Twenty-eight neonates with moderate or severe HIE treated with TH were included in the present study. MRI images obtained on day of life 4-7 were scored according to standardized injury criteria. Unfavourable outcome was defined as death or significant grey matter injury on MRI according to a previously validated scoring system. A significantly higher cooling device output temperature was seen in infants with an unfavourable outcome. All neonates who required the mattress to provide a temperature ≥32°C to maintain their core body temperature at 33.5°C had a high likelihood of unfavourable outcome (likelihood ratio = 14.4). By contrast, infants who never required a device output temperature ≥32°C had a low likelihood of an unfavourable outcome (likelihood ratio = 0.07, P < 0.001). Infants with significant grey matter injury on MRI require less active cooling to maintain target temperature during TH. The cooling device output temperature has the potential to be an easily accessible physiological biomarker and predictor of injury and mortality in neonates with moderate or severe HIE.
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The Journal of physiology · Jan 2020
Differential impact of two critical respiratory centres in opioid-induced respiratory depression in awake mice.
The main cause of death from opioid overdose is respiratory depression due to the activation of µ-opioid receptors (MORs). We conditionally deleted MORs from neurons in two key areas of the brainstem respiratory circuitry (the Kölliker-Fuse nucleus (KF) and pre-Bötzinger complex (preBötC)) to determine their role in opioid-induced respiratory disturbances in adult, awake mice. Deletion of MORs from KF neurons attenuated respiratory rate depression at all doses of morphine. Deletion of MORs from preBötC neurons attenuated rate depression at the low dose, but had no effect on rate following high doses of morphine. Instead, high doses of morphine increased the occurrence of apnoeas. The results indicate that opioids affect distributed key areas of the respiratory network in a dose-dependent manner and countering the respiratory effects of high dose opioids via the KF may be an effective approach to combat overdose. ⋯ The primary cause of death from opioid overdose is respiratory failure. High doses of opioids cause severe rate depression and increased risk of fatal apnoea, which correlate with increasing irregularities in breathing pattern. µ-Opioid receptors (MORs) are widely distributed throughout the brainstem respiratory network, but the mechanisms underlying respiratory depression are poorly understood. The medullary pre-Bötzinger complex (preBötC) and the pontine Kölliker-Fuse nucleus (KF) are considered critical for inducing opioid-related respiratory disturbances. We used a conditional knockout approach to investigate the roles and relative contribution of MORs in KF and preBötC neurons in opioid-induced respiratory depression in awake adult mice. The results revealed dose-dependent and region-specific opioid effects on the control of both respiratory rate and pattern. Respiratory depression induced by an anti-nociceptive dose of morphine was significantly attenuated following deletion of MORs from either the KF or the preBötC, suggesting cumulative network effects on respiratory rate control at low opioid doses. Deletion of MORs from KF neurons also relieved rate depression at near-maximal respiratory depressant doses of morphine. Meanwhile, deletion of MORs from the preBötC had no effect on rate following administration of high doses of morphine. Instead, a severe ataxic breathing pattern emerged with many apnoeas. We conclude that opioids affect distributed areas of the respiratory network and opioid-induced respiratory depression cannot be attributed to only one area in isolation. However, countering the effects of near maximal respiratory depressant doses of opioids in the KF may be a powerful approach to combat opioid overdose.